Biochemical and Electron Microscopic Image Analysis of the Hexameric E1 Helicase*

Erik T. FoutsDagger §, Xiong Yu, Edward H. Egelman, and Michael R. BotchanDagger parallel

From the Dagger  Department of Molecular and Cell Biology, University of California, Berkeley, California 94720 and the  Department of Cell Biology and Neuroanatomy, University of Minnesota Medical School, Minneapolis, Minnesota 55455

    ABSTRACT
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Abstract
Introduction
References

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 Å thick and 125 Å 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.

    INTRODUCTION
Top
Abstract
Introduction
References

The synthesis of duplex DNA is a complex enzymatic process that requires the coordination of large numbers of proteins. The mechanisms are elaborate in part because the enzymes that use the complementary template strand as a guide for nucleotide incorporation catalyze this synthesis only in the 5' to 3' direction. Given the antiparallel nature of the duplex this usually requires that two synthetic enzymes move in opposite polarities on the two strands. Synthesis of the so-called lagging strand is discontinuous and requires the cyclical association of the enzyme, while synthesis of the other strand is continuous. Nevertheless, in many prokaryote replication systems it is clear that coordination of these enzymes is achieved and maintained by a dimeric polymerase that creates a looped DNA structure in the lagging strand. This loop is mediated by multiple protein-protein interactions across the growing fork (Ref. 1, and references therein). Helicases are enzymes that can catalyze the unwinding of the template strands ahead of the fork, thus allowing for new complementary strand DNA synthesis. They were initially discovered as ancillary factors required for synthesis, but recently this view of the helicase activity has been characterized as "naive" or at least incomplete (2). Compelling evidence has been presented demonstrating that the helicase is an integral member of a large protein complex that serves as a molecular motor or pump for the replication apparatus empowering the polymerase and increasing the rate of DNA polymerase synthesis (3). The Escherichia coli dnaB helicase also plays a critical function in establishing the asymmetry at the growing fork. The helicase tracks on the lagging strand template but through interactions it holds the leading strand DNA polymerase while allowing for recycling of the other DNA polymerase (4). How helicases actually convert the binding and hydrolysis of ATP into mechanical energy resulting in DNA unwinding and can concomitantly achieve relative movement along the DNA is presently under intense investigation (5, 6). While many issues remain unresolved, it seems as if the well studied replication helicases of E. coli (and its phage encoded ones) engage DNA by encircling at least one of the DNA strands that have been prepared for this loading by other replication proteins (7-10). Thus, for example, the dnaB helicase is loaded onto DNA in complex with dnaC to a duplex structure at oriC already melted by the dnaA protein (11).

In eukaryotes, despite the ubiquitous presence of many DNA helicases (12), little is known about the relationship between such enzymes and the replication complex. However, the importance of such proteins in eukaryotic DNA replication is highlighted by the fact that many DNA viruses that replicate in the nucleus encode a helicase. One type of such viral helicase can initiate unwinding from within duplex structures not prepared for activity by prior melting. These helicases encoded by the herpes simplex virus, papillomaviruses or the SV40, and polyoma viruses can serve as DNA initiators by first recognizing small repeat motifs within the origin of replication. Thus, a particularly challenging structural problem exists in determining how these proteins convert from a site-specific DNA binding mode to a helicase. For the SV40 T antigen, monomers bind to pentameric base pair repeats utilizing specific nucleotide base information. After double hexamer formation on the DNA and ATP binding DNA-protein contacts shift toward sugar-phosphate interactions (13). A complex series of steps must therefore occur to change both the oligomeric state of the protein and the nature of its contacts with DNA. Presumably, both the DNA and ATP could be allosteric effectors of this change, but in the case of T antigen ATP is sufficient for hexamer formation. Similarly for the HSV-1 origin binding protein UL9 a pair of dimers interact with each other and bend the ori region as duplex DNA-binding proteins. In the presence of ATP the complex becomes an active unwinding enzyme that can extrude catenated single-stranded loops (14).

The papillomaviruses provide a unique system for analyzing this assembly and transition process. The bovine papilloma virus type 1 (BPV-1)1 encodes a 68-kDa phosphoprotein (E1) that binds site specifically to two sets of short repeats organized as inverted repeats at the viral origin of replication (15, 16). The protein is also an ATPase (17) and a helicase able to initiate unwinding from within a duplex DNA circle (18, 19). However, unlike UL9 or the SV40 T antigen, E1 requires in vivo an ancillary viral factor in order to be targeted to the viral origin of replication (20, 21). The E1 protein in a cell-free DNA replication system can direct origin-specific DNA replication; however, this activity is greatly stimulated by E2 and at limiting dilutions of E1 the in vitro DNA replication becomes absolutely dependent upon E2 (22). This dependence upon E2 reflects the cooperative interaction between E1 and E2 in binding to viral DNA (22-25). The E2·E1·DNA complex initially assembled at the origin consists of two or four monomers of E1 spanning the inverted repeats and an E2 dimer occupying an adjacent binding site (15). Interestingly, the E2 dimer must leave this complex in an ATP-dependent reaction before higher-order complexes of E1 assemble (26, 27). Therefore, it seems as if E2 might stabilize the site-specific DNA binding conformation of E1 and either mask or allosterically block the helicase transition. In vivo, this chaperone process seems likely to have evolved to increase the likelihood of origin occupancy and perhaps to allow for the coordination of other activities of E1 with the transcriptional and segregation functions of E2 (28, 29). In any case understanding the differences between the E1 assembled in the preinitiation E1·E2 complex and as an active helicase on the DNA should provide insights into the transitions that must occur for all of the viral initiator proteins discussed above.

E1 is believed to be structurally related to the SV40/polyoma virus-encoded large T antigens. Both helicases track on the leading strand template (23), and the overall organization of the open reading frames are similar. For instance, the nuclear localization domain is proximal to the site-specific DNA-binding domain and the conserved "Walker" A and B boxes of the ATP-binding domains are equivalently spaced and are about 200 amino acids displaced from the DNA-binding domain (30). Moreover, mutations of these conserved motifs affect activity in expected ways (17, 19, 31, 32). However, many of these alignments can now be made for other members of the SF3 family of DNA helicases that do not have analogous activities such as those from parvoviruses and the human herpes 6 virus (33). It is therefore important to analyze how E1 as an active unwinding enzyme actually engages DNA. In this report we use both biochemical and electron microscopy techniques to establish that E1 initiates unwinding from the origin site and unwinds DNA bidirectionally; moreover a bi-lobed double hexameric complex similar to the images obtained for T antigen was observed at the start site. In these complexes the DNA is likely to take a straight path through the double rings. Biochemical and electron microscopic analysis showed that, as anticipated, unwinding activity correlates with the formation of hexamers. Image analysis of the hexameric structures showed that the molecules do form toroidal rings with a central hole; these molecules possess either 3- or 6-fold symmetries. Surprisingly, a significant fraction of the hexamers show density in the central hole. Such "filled" centers have not been observed for other hexameric helicases but we speculate that the protein has several conformational states and that conformational flexibility may indeed be a general feature of this family.

    MATERIALS AND METHODS

Plasmid Construction and DNA Substrates-- pKSO has been described previously (22). pSS3, pSS3-LI5C, and pSS3-Delta opal are described by Mendoza et al. (16). The BPV-1 origin containing fragment generated by BamHI and HindIII restriction enzyme digest of pKSO was inserted into the pACYC177 vector linearized by BamHI and HindIII to give rise to pCLO. The 429-base pair BPV-1 origin containing substrate DNA used in the fragment unwinding assay and for DNA induced E1 oligomerization was generated by digesting pKSO with the EcoRI and PvuII restriction endonucleases. The 242-base pair origin containing DNA fragment used in EM linear compaction studies was generated by digesting pKSO with EcoRI and BamHI restriction endonucleases. Both of the duplex fragments were purified from agarose gels. The sequence of the 10-base pair oligomer used for DNA induced E1 oligomerization is 5'-AACAACAATC-3'. The E1 construct used for overexpression in E. coli, pGEX-2TK-E1, was generated by cloning the E1 open reading frame from the pET11-GST-E1 plasmid (25) into the pGEX-2TK vector (Pharmacia number 27-4587-01, GenBank accession number U13851). The integrity of the boundaries for the E1 coding sequence was verified by DNA sequencing.

Protein Purification-- The BPV-1 E1 protein was purified from Sf9 cells infected with a recombinant baculovirus expression vector by immunoaffinity chromatography as described by Yang et al. (22). The E1 protein purified from E. coli began with transforming XA90 cells with the pGEX-2TK-E1 expression vector and proceeded according to methods described by Sedman et al. (25) as modified by C. Sanders.2 In brief, extracts from isopropyl-thio-beta -D-galactopyranoside-induced cells were prepared, cleared of nucleic acid by a Polymin P (10% w/v) precipitation (0.5% w/v final) centrifuged by a 25,000 × g spin for 20 min. E1 protein in the supernatants was precipitated by 65% ammonium sulfate at 4° C. The recovered protein was purified by adsorption to glutathione-Sepharose beads and eluted in buffer containing 20 nM glutathione. The GST moiety was cleaved with thrombin and the E1 was further purified by chromatography on an S-Sepharose column (Pharmacia). The E1 containing fractions were pooled, dialyzed against E1 dialysis buffer (20 mM pKPO4, pH 7.5), 150 mM potassium glutamate, 1 mM EDTA, 1 mM DTT, and 10% glycerol aliquoted, and stored at -80° C.

Unwinding Assays-- The unwinding reactions using either covalently closed circular DNA or duplex DNA fragment substrates were performed as described previously (19).

Electron Microscopy and Measurement of DNA Regions-- Unwinding reactions using substrates indicated in the text were incubated at 32° C for 1 h. Micrographs of linearized DNA were prepared by adding 6 units of the indicated restriction enzyme and incubating for an additional 20 min. Reaction products were fixed by the addition of glutaraldehyde to 0.6% and purified by filtration through a 0.5-ml Bio-Gel A5-M column (Bio-Rad) and applied to glow-discharged carbon grids coated with 2 mM spermidine. The grids were then rotary shadowed with tungsten. Photographs were taken at × 30,000 with a JEOL 1200 EX electron microscope at an acceleration voltage of 80 kV (61). Micrographs of E1 complexes bound to a BPV-1 origin containing DNA fragment for linear compaction studies were prepared using the same method described above. Measurement of duplex regions was performed by projecting photographic negatives onto a Numonics digitizing tablet.

Image Analysis-- The E1 protein (3 mM concentration, in 25 mM KPO4, 60 mM NaCl, 1 mM EDTA, 1 mM DTT, pH 7.5) was incubated with 18 mM of a 60-mer oligonucleotide for 30 min at 30° C, and then applied to glow-discharged grids and stained with 2% (w/v) uranyl acetate. Electron micrographs were recorded under minimal dose conditions (with no prior exposure to the high magnification electron beam prior to recording) at × 30,000 magnification, using a JEOL 1200 EXII microscope. Negatives were scanned with a Leaf 45 microdensitometer, with a sampling interval of 4 Å/pixel. Images of rings were masked into 44 × 44 pixel arrays (corresponding to 176 × 176 Å), band-pass filtered (between 1/160 and 1/12 Å-1), scaled to zero mean density, and the contrast was normalized. After applying a reference-free alignment (44), images were ranked by the strength of either the 3- or 6-fold power, as described in Yu et al. (39). For the 6-fold ranking, we excluded those images that contained a significant 3-fold power. After sorting based upon rotational symmetry, images were then sorted based upon the strength of the integrated density within a 16-Å radius area at the rotational axis of the ring.

Radiolabeling of E1-- The 7 amino acid NH2-terminal tag on the E1 purified from overexertion in E. coli contains a recognition sequence as well as a serine that can be specifically phosphorylated by bovine heart muscle kinase. A typical 30-µl labeling reaction contains 2.5 µg of E1 (1.3 µM final), 10 units of bovine heart muscle kinase (Sigma P-2645), and 2 µl of [gamma -32P]ATP at 6000 Ci/mM in 20 mM Tris (pH 7.5), 100 mM NaCl, 12 mM MgCl2, and 0.1 mM DTT. The reaction is incubated at 4° C for 30 min and stopped with the addition of EDTA to 25 mM. E1 was purified away from free 32P and nucleotides by Sephadex G-25 column chromatography (NAP-10 column, Pharmacia number 17-0854-02).

Electrophoresis of E1 Complexes-- Native gel electrophoresis of E1 was performed as indicated in the text. For analysis of cross-linked E1 complexes, the E1 sample was boiled for 5 min in Laemmli SDS loading buffer (pH 8.8) + 130 mM beta -mercaptoethanol. The samples were then loaded onto polyacrylamide gradient gels containing an acrylamide:bis ratio of 80:1. A stacking phase was not used and electrophoresis was carried out in 25 mM Tris, 250 mM glycine, 0.1% SDS with a final pH of 8.8. Current was held constant at 10 mA.

Glycerol Gradient Sedimentation-- E1 purified from Sf9 cells infected with a recombinant baculovirus was centrifuged in a 15-35% glycerol gradient with 0.1 KCl-HEMG + 0.01% Nonidet P-40 (62). For E1 purified from overexpression in E. coli, the protein was centrifuged as above with the following modification: a gradient of 15-37% glycerol in 1 M NaCl, 20 mM HEPES (pH 7.5), 5 mM EDTA, and 0.01% Nonidet P-40 was used.

    RESULTS

E1 Unwinds DNA Bidirectionally from the ori Site-- BPV-1 replicates bidirectionally in vivo and in cell-free extracts (22, 34, 35). With purified replication components wherein E1 provided the only helicase activity (36), fully replicated circles were obtained. Furthermore, acting on covalent closed circles, E1 is capable of producing a highly unwound DNA (form U) consistent with complete denaturation of the circles (19, 23). It was therefore anticipated that E1 as a replicative helicase must be capable of processive unwinding that spreads bidirectionally from the BPV-1 origin region. Electron microscopy and an in vitro unwinding assay were employed to map both the location and extent of unwinding of BPV-1 genomic DNA by E1. Covalently closed circular DNA was relaxed with calf thymus topoisomerase I and then incubated with purified E1, ATP, topoisomerase I, and E. coli SSB protein. For this analysis, we used the plasmid pSS3 that contains an intact BPV-1 genome cloned into pUC18. The samples were fixed with glutaraldehyde, purified by gel filtration, and linearized by restriction endonuclease hydrolysis at a unique site. Representative images are shown in Fig. 1, A-D. The lengths of the unwound regions of DNA and total contour lengths were measured to determine both the size and position of the unwound regions with respect to the entire length. A compilation of data is presented in Fig. 1E. As each of the molecules could be aligned in either of two directions (and one such orientation chosen for each to make the alignment) it was necessary to repeat this analysis with a different unique single cutter. This separate set increases the statistical significance of the conclusions. Such data obtained with either AflII or SacI defining the ends (Fig. 1E) show that unwinding initiates at the ori site and that denaturation spreads bidirectionally from that position.


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Fig. 1.   Electron micrographs of unwound BPV-1 origin containing plasmid DNA. Unwound pSS3 DNA molecules cleaved with either AflII (A and B) or SacI (C and D) restriction enzymes. The molecules were applied to carbon grids and rotary shadowed with tungsten, as described under "Materials and Methods." The single-stranded DNA appears thicker than duplex DNA, because the single-stranded DNA is coated with E. coli SSB and/or E1. Bar in D = 200 nm. E, measurements of unwinding of BPV-1 origin containing DNA in vitro. To determine the extent, direction, and location of unwound regions, molecules were photographed, and the length of duplex DNA was measured by projecting negatives onto a Numonics digitizing tablet. The positions of unwound regions (black boxes) were plotted below a linear map of the plasmid. The relative position of the origin in base pairs is indicated at the bottom of the histograms. The standard of deviation for total length was 9%.

These results are compatible with those presented previously by Seo et al. (18), who showed that E1-dependent formation of form U was dependent upon the integrity of ori. However, our earlier results (19) on form U production showed little dependence upon origin sequences, a result that might predict scattered bubble positions. With different preparations of the E1 protein we performed in vitro unwinding assays with various mutant templates. Mutations were engineered into the E1-binding site to determine whether the E1 DNA-binding site contributed quantitatively to the level of form U DNA produced. Two mutants were derived from the plasmid pSS3; LI5C contains a 5-base pair linker insertion between the inverted repeat, and for Delta  OPAL the entire palindrome is deleted. The reaction products for each were separated by agarose gel electrophoresis, blotted to filters, and probed with pUC18. PhosphorImage analysis of these Southern blots was used to determine the amount of form U DNA generated (Fig. 2). The data do show that while all substrates are capable of directing unwinding the wild type ori site is indeed preferred. It therefore seems likely that when a template contains a bona fide ori with E1 sites organized in such a way as to allow for helicase formation, such sites will be utilized in vitro. We do not understand why such preferences were not detected earlier, but perhaps this specificity is sensitive to monomer E1 concentration and variations in this regard might influence the data.


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Fig. 2.   E1 helicase prefers origin-containing substrates. Unwinding reactions were performed with the following substrates: plasmid pSS3, which has a wild-type E1-binding site, plasmid pSS3-Delta opal, which lacks the E1-binding site, or plasmid pSS3-LI5C which has a 5-base pair linker insertion between the inverted repeats that make up the E1 DNA-binding site. The E1 concentrations were held constant (368 nM) and lambda  genomic DNA was titrated into the reactions as nonspecific competitor DNA. The reaction products were Southern blotted and radioactivity quantitated by PhosphorImager analysis. The amount of highly unwound form U DNA generated by helicase activity is plotted. The graph indicates that substrates with wild-type E1-binding sites are more effectively unwound than those lacking E1 sites.

The E1 Protein Forms Hexamers and Oligomerization Correlates with Helicase Activity-- To determine the oligomeric states of E1 we analyzed the sedimentation profiles of the baculovirus-purified E1 incubated in the presence and absence of ATP. Fractions from a glycerol gradient were collected, and the positions of the E1 protein determined by SDS-PAGE and Western blotting using polyclonal E1 antisera. The protein profiles of the gradients (Fig. 3) indicate that E1 purified by single step affinity chromatography sediments in a heterogeneous manner. In addition, it is clear from this analysis that ATP is not sufficient for the oligomerization of E1 monomers. The molecular mass markers suggest that the slowest migrating peak corresponds to monomeric E1 (68 kDa) and the second peak a hexameric form (408 kDa). Fractions at the bottom of the tube likely correspond to aggregates. Glycerol gradient fractions containing the putative hexamer fraction and monomer fractions were analyzed by electron microscopy. The images of the putative hexamer peak showed a typical 6-membered toroidal structure (Fig. 3) bearing striking similarity to the published micrographs of hexameric helicases (8, 10, 37-39). The monomeric peak showed no such structures (data not shown).


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Fig. 3.   Glycerol gradient analysis of E1. 4.5 mg of purified E1 (1.3 µM final concentration) was incubated for 10 min at 37° C in 20 mM HEPES (pH 7.5), 50 mM KCl, 7 mM MgCl2, in the presence or absence of 4 mM ATP. The reactions were subjected to centrifugation through gradients of 15-35% glycerol as described under "Materials and Methods." Fractions were collected and subjected to SDS-PAGE and Western blotting. A Western blot of all fractions across the gradients is shown. The position of molecular weight markers run in parallel gradients is indicated above each protein profile (669 kDa, thyroglobulin; 232 kDa, catalase; 66 kDa, bovine serum albumin). The starting material was loaded in the lane following the last collected gradient fraction and is labeled LOAD. The protein profiles of the gradients indicate E1 sediments as two species of approximately 68 and 400 kDa. The material having a molecular mass greater than 669 kDa is thought to represent highly aggregated forms of E1. The glycerol gradient fraction containing the high molecular mass species of E1 (in the presence of ATP, molecular mass approximately 400 kDa) was applied to glow-discharged carbon grids and stained with 2% (w/v) uranyl acetate. The electron micrographs shown were taken at × 30,000 with a JEOL 1200 EX electron microscope at an acceleration voltage of 80 kV. Bar, 250 Å.

Protein preparations from baculovirus vectors showed a mixture of forms, and to study a more homogeneous population and to investigate the relationship between the monomer and hexamer forms in more detail, we purified E1 from E. coli cells using the methods described by Sedman et al. (25). Indications from spectrophotometric 280/260 absorption ratios for baculovirus E1 preparations were that the yields of hexameric peaks and aggregated material correlated with trace nucleic acid contaminations. We therefore explored the notion that DNA binding might be a factor in oligomerization. The E. coli E1 possesses an amino-terminal sequence which can be phosphorylated to high specific activity in vitro; such modification has no effect upon helicase activity or other biochemical tests described below (data not shown). The purified material sedimented as a homogeneous monomeric fraction (Fig. 4B). Moreover, this protein's sedimentation behavior was not affected by ATP binding. The E. coli protein was found to be active in cell-free DNA replication and its activity was stimulated by E2 (data not shown).


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Fig. 4.   DNA stimulates E1 oligomerization. A, radiolabled monomeric E1 protein (128 nM) was incubated in the presence (lanes 6-10) or absence (lanes 1-5) of a 429-base pair BPV-1 origin containing DNA fragment (3.8 nM). Glutaraldehyde was titrated into the reactions (0.005, 0.010, 0.020, and 0.040% final) followed by boiling in SDS sample buffer + beta -mercaptoethanol. The reactions were analyzed by electrophoresis on a denaturing gradient gel (4.4-20% acrylamide) and stained with Coomassie Brilliant Blue to allow identification of molecular weight markers. This was followed by drying of the gel and autoradiography. An autoradiogram of the gel is shown with the positions of molecular weight markers are indicated on the left (Kaleidoscope Prestained Standard, Bio-Rad 161-0324) and right (Cross-Linked Phoshphorylase b, Sigma P 8906). B, glycerol gradient analysis of E1 oligomers induced by DNA. Radiolabled monomeric E1 (64 nM) was incubated in the presence or absence of a single-stranded DNA 10-base oligomer (10-mer, 500 nM) at room temperature for 20 min in 25 mM KPO4 (pH 7.5), 75 mM NaCl, 5 mM EDTA, 1 mM DTT, and 1 mg/ml bovine serum albumin. Glutaraldehyde was added to a 0.02% final concentration and incubated for 20 min at room temperature. Glutaraldehyde was removed from the reactions by Sephadex G-25 column chromatography (NAP-10 column, Pharmacia 17-0854-02). The protein containing fractions were pooled for each reaction and subjected to centrifugation through gradients of 15-37% glycerol as described under "Materials and Methods." Fractions were collected an the amount of radioactivity in each fraction was determined by scintillation. A graph of the radioactivity plotted against position in the gradient is shown. The positions of molecular weight markers run in a parallel gradient is indicated at the top of the plot. C, the low and high molecular weight peaks from the glycerol gradients in B were boiled in SDS sample buffer + beta -mercaptoethanol and analyzed by denaturing gradient gel electrophoresis (4-10% acrylamide) and stained with Coomassie Brilliant Blue to allow identification of molecular weight markers. This was followed by drying of the gel and autoradiography. Two autoradiograms are presented representing two lengths of exposure time. H (lanes 2 and 4) represents the high molecular weight E1 species isolated from the glycerol gradient in B, and L (lanes 3 and 5) represents the low molecular weight E1 peak. The lane marked M (lane 1) is the Coomassie-stained cross-linked phosphorylase b molecular weight marker (Sigma P 8906) with the weights indicated to the left. To the right, the positions of additional molecular weight markers (Kaleidoscope Prestained Standard, Bio-Rad 161-0324) are indicated.

The monomeric radiolabeled E1 was incubated with a 429-bp duplex DNA fragment in the absence of ATP and Mg2+. Reactions were fixed employing titrations of glutaraldehyde and subjected to denaturing polyacrylamide gradient electrophoresis (Fig. 4A). A ladder of cross-linked phosphorylase or commercial prestained standards (Kaleidoscope, Bio-Rad) were used as gel standards. The results show that duplex DNA can promote oligomerization and the data confirm that hexameric forms of E1 predominate. In the absence of DNA no multimerization was detected at any concentration of cross-linking agent. These data were obtained both with nonspecific duplex and single-stranded DNA. Even very small oligonucleotides can catalyze this oligomerization. In the presence of a 10-base single strand oligomer (in the absence of ATP), E1 sediments as a hexamer in a glycerol gradient (Fig. 4B). Analysis of the protein peaks collected from these gradients (after glutaraldehyde fixation) by denaturing acrylamide gel electrophoresis confirms that the high and low molecular weight peaks represent hexameric and monomeric E1 forms (Fig. 4C).

To explore the functional significance of this oligomerization we sought to correlate E1 unwinding activity with its multimeric state. To obtain such correlations we chose the duplex unwinding assay utilizing a duplex restriction fragment that contains the BPV-1 ori sequence. In previous experiments from our laboratory (19), unwinding in this assay was dependent upon ori sequences and absolutely required an SSB. In two parallel sets of reactions we either followed the oligomeric state of E1 across a range of protein concentrations (3.75 to 480 nM) (Fig. 5A) or the state of the duplex DNA (4.2 nM) over the same protein titration (Fig. 5B). In these side-by-side experiments reaction conditions were identical with the exception that SSB was not present in the data obtained for Fig. 5A. As E1 assembles on the DNA in the presence of ATP/Mg2+ and E. coli SSB, the duplex is melted and converted to single strands. The ability of E1 to act as a duplex unwinding enzyme is very cooperative (Fig. 5C) with respect to concentration and correlates with oligomerization. Hexamers and high forms (perhaps double hexamers) correlate with such activity. At 60 nM E1 some unwinding is first detected and at this concentration hexamers and notably higher forms are first detected.


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Fig. 5.   Oligomerization of E1 correlates with helicase activity. A, titration of radiolabled E1 monomers (3.75, 7.5, 15, 30, 60, 120, 240, and 480 nM) into reactions containing 25 mM KPO4 (pH 7.5), 75 mM NaCl, 5 mM EDTA, 1 mM DTT, 1 mg/ml bovine serum albumin, and a 429-base pair BPV-1 origin containing DNA fragment (4.2 nM) for 20 min at room temperature. Glutaraldehyde was added to a 0.04% final concentration and incubated for 20 min at room temperature. Reactions were boiled in SDS sample buffer + beta -mercaptoethanol and equal amounts of E1 protein loaded onto a denaturing acrylamide gradient gel (4-10%). Autoradiography was performed on the dried gel. The positions of prestained molecular weight markers are indicated. Cross-linked radiolabled E1 hexamer (408 kDa) purified from a glycerol gradient (see Fig. 6) was loaded as a mass marker (lane 1). B, fragment unwinding assay. The helicase assay was performed with the same E1 titration and DNA levels as above. The DNA fragment is the same as in A and is radiolabled, while the E1 protein underwent a mock radiolabeling reaction with cold ATP. The resulting DNA products were assayed by agarose gel electrophoresis and autoradiography. The lane labeled boiled provides markers for the ssDNA and double-stranded DNA positions. C, the amount of denatured DNA was determined by PhosphorImager analysis and is plotted against E1 protein concentration.

DNA Takes an Apparent Linear Path Through a Bilobed E1 Complex-- From the data in Fig. 5 there is a suggestion that complexes of higher order than hexamer may be the most efficient in unwinding duplex DNA. For SV40 T antigen direct experiments indicate that a double hexameric form of this helicase may provide the most effective enzymatic complex for such purposes (40, 41). To extend this comparison we asked if a bilobed structure, taken as a measure of double hexamer formation for T antigen (42, 43) could be observed for E1. Purified E1 protein was incubated (in the absence of ATP) with a 242-base pair duplex DNA fragment containing a centrally located ori sequence. Electron micrographs were recorded of the protein-DNA complexes (Fig. 6A). The characteristic "double doughnut" images were prevalent. The length of the DNA fragments with and without bound protein was measured by projecting electron micrograph negatives onto a numonics digitizing tablet (Fig. 6B). We found that the DNA length distribution does not change upon engaging E1. This absence of a linear compaction of the protein-bound DNA indicates that the DNA likely takes on a linear path through the E1-protein complex. The data clearly rule out any mode of binding which would require the DNA to wrap around the helicase (Fig. 6C). Similar DNA compaction studies performed on the E. coli dnaB helicase (7) and T antigen (42, 43) have been similarly interpreted; however, we would point out that the standard deviation in length measurements (~9%) is very close to what might be expected for more complex models wherein one strand passes through one hexamer and out through the top of the same shell (see line 2, Fig. 6C). To resolve this point higher resolution or other approaches to analyzing these structures is required.


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Fig. 6.   E1 complex bound to origin DNA. A, electron micrographs of purified E1 bound to a 242-base pair DNA fragment containing a centrally located BPV-1 origin sequence. Samples were prepared and spread as described under "Materials and Methods." Bar, 100 nM. B, measurements of DNA lengths with or without bound E1 protein were performed by projecting electron micrograph negatives onto a Numonics digitizing tablet. The length distributions of 17 DNA molecules without E1 and 55 molecules with bound E1 are shown. The distributions are identical indicating that binding of E1 does not linearly compact the DNA. C, models for E1 DNA binding. Binding modes are presented in which the length of DNA would be unchanged upon binding of a hexameric protein ring. Examples are also provided where the DNA is wrapped around the helicase ring resulting in linear compaction of the nucleic acid. The predicted changes in DNA length are shown. These calculations are based on the dimensions of the E1 hexameric ring provided by three-dimensional image reconstruction (145 Å maximum diameter × 50 Å thickness) and the length of the 242-base pair B-DNA being 823 Å. (standard deviation for DNA length = 9% = 74 Å = 22 base pairs).

Image Analysis of E1 Hexameric Ring-- To obtain a clearer analysis of the ring structures, minimal dose electron microscopy and image analysis were used to study the organization of the oligomeric state of the E1 protein. Fig. 7 shows electron micrographs where both top views of the rings (Fig. 7a, formed with an oligonucleotide) and side views of the rings stacked on double-stranded DNA (Fig. 7B) can be seen. Images of 968 top views of the rings were averaged together, using a reference-free alignment procedure (44). The resulting average (not shown) suggested a hexameric structure, but subsequent analysis indicated that the population of rings was non-homogeneous. First, a sorting by rotational power (as done for DnaB protein in (39)) indicated that a subset of the rings had a significant 3-fold rotational power, consistent with the asymmetric unit in these rings being a dimer. Trimers of dimers has previously been observed for the hexameric rings formed by the DnaB protein (39, 45) and the RecA protein (46). Fig. 8, a and b, show the 6-fold symmetric averages (containing 678 rings), while Fig. 8, c and d, show the 3-fold symmetric average (containing 100 rings). The rotational power spectra for the 6- and 3-fold symmetric averages are shown in Fig. 8, i and j, respectively. The main difference between the 6-fold symmetric rings and the 3-fold symmetric ones is that there appears to be a modulation of the projected subunit density in the 3-fold symmetric averages, such that there are alternating "strong" and "weak" subunits. In addition, the outermost ends of the subunit arms appear to move in toward the center for the three weaker subunits in the 3-fold conformation. Both forms of the ring appear to be about 125 Å in diameter.


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Fig. 7.   Electron micrographs of the E1 protein rings after incubation with an oligonucleotide (a) or with double-stranded DNA and ATP (b). The 500-Å scale bar in a applies to both a and b. Averaged side views of the rings in b are shown in c-e. The average in c contains 217 images, while the subaverages in d and e contain 44 and 52, respectively. The 100-Å scale bar in d applies to c-e. The double arrow in d is 80 Å long, indicating the approximate spacing between three adjacent rings.


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Fig. 8.   The E1 rings appear with either a hole in the center (a and c) or with a plug of density in the center (b and d). Independent of whether there is a hole or a plug in the center, the rings have either a 6-fold symmetry (a and b) or a 3-fold symmetry (c and d). The images in e and f are the averages in a and b, respectively, but with an exact 6-fold symmetry imposed, while the images in g and h are the averages in c and d, respectively, but with an exact 3-fold symmetry imposed. The number of individual ring images in the averages shown is: a, 400; b, 278; c, 56; and d, 44. The arrows in a and c indicate a weak density that is located asymmetrically in the central channel, consistent with what might be expected from the bound oligonucleotide. The scale bar in h is 100 Å. The rotational power spectrum (63) for the average of 774 E1 rings showing a 6-fold rotational symmetry (with no 3-fold) (i), and the rotational power spectrum for an average of 100 E1 rings showing a significant 3-fold rotational symmetry (j). The spectra were calculated between the radial limits of 12 to 68 Å.

Second, the density within the central channel appeared to be continuously variable. The images contained in the 6- and 3-fold averages were then sorted based upon the strength of this central density. Fig. 8a shows an average of 400 6-fold symmetric rings with a strong hole near the center, while Fig. 8b shows an average of 278 6-fold symmetric rings with a "plug" of density in the center. Similarly, Fig. 8c shows an average of 56 3-fold symmetric rings with a strong hole near the center, and Fig. 8d shows an average of 44 3-fold symmetric rings with a plug in the center. There did not appear to be any correlation between the strength of the 3- or 6-fold power and the strength of the central density. Furthermore, both the relative strength of the 3-fold rotational power and the relative strength of the central density appeared to be continuously variable parameters. Thus, the groupings that are shown in Fig. 8 represent arbitrary divisions. For example, averages could have been created in Fig. 8, b and d, showing a stronger central density by using fewer images, just as averages could have been generated in Fig. 8, c and d, showing a slightly stronger 3-fold power by using fewer images.

Symmetrized versions of the averages in Fig. 8, a-d, are shown in Fig. 8, e-h, respectively. One consequence of the symmetrization, which eliminates noise, is that asymmetric features disappear. However, this can also obscure real asymmetric features. The central holes in Fig. 8, a and c, are displaced from the central axis, while the symmetrization forces these holes to lie on the central axis in Fig. 8, e and g. It is likely that this displacement of the stain-filled hole from the central axis is due to the binding of the 60-nucleotide oligomer, since this mass might be expected to be bound within the central channel to only one or two of the subunits, as shown for the T7 gp4 hexameric helicase (10). Thus, the bound oligonucleotide would be filling some of the central channel (indicated by arrows in Fig. 8, a and c), leading to an asymmetric location of the stain-filled hole.

While the averages in Fig. 8 have a slight hand, the degree of chirality is much less than that observed for DnaB (39, 45), T7 gp4 (10), or SV40 large T antigen (37). We therefore checked to see if the lack of a strong hand arose from averaging together individual projection images that were related by mirror symmetry. This would occur if the rings were randomly oriented on the grid, as opposed to predominantly one side adsorbing to the grid. We used the highly chiral average of SV40 large T (37) as a reference to align all images, and then did the alignment against the mirror image of the reference. Images were ranked based upon the coefficient of correlation against the reference, and averages were then created from those with the strongest correlation using the reference-free alignment (44). The results of this procedure suggested that there was no strong chirality present, as no averages were generated with the opposite band to that shown in Fig. 8. Thus, the rings appear to predominantly adsorb to the grid by the same surface.

Conditions were found where "side" views of the E1 rings could be obtained by binding them to double-stranded DNA molecules in the presence of ATP (Fig. 7b). Fig. 7c shows an average generated by aligning 217 side view images, each image containing three rings. The spacing between adjacent rings is about 50 Å, and unless there is a large degree of interdigitation, this would be the thickness of each ring. Since there does not appear to be a large continuous density running between adjacent rings, a large degree of interdigitation appears unlikely. The spacings between the rings were observed to be quite variable, and a number of different characteristic side views appeared to be present, as well. We therefore sorted the images into subgroups using correspondence analysis (47) and Fig. 7, d and e, show subaverages generated from 44 and 52 different rings, respectively. Since the alignment method used to generate the averages in Fig. 7, d and e, only examined the density of the central ring (of the three contained in each image) the density of the central ring is averaged properly, while the density of the surrounding rings is smeared due to their variable spacing. Nevertheless, the spacing of about 80 Å seen in Fig. 7d between the two outer rings suggests that these rings may be as close together as 40 Å. These side views help establish that the E1 ring is about 40-50 Å in thickness.

    DISCUSSION

Although the site-specific DNA-binding domains of the papillomavirus E1 have no homology to the SV-40/polyoma large T antigens, both of which are highly homologous to each other, and the nucleotide sequence motifs that serve as binding sites are distinct for these papillomaviruses; the initiator proteins assemble as helicases in remarkably similar ways. In both situations a double-ringed structure assembles at the origin site, and this helicase activity is capable of denaturing DNA bidirectionally from the assembly point. As we have shown here the toroidal rings formed by BPV-1 E1 are hexameric as are the T antigens.

It is also significant to point out that some differences have been uncovered between these helicases, particularly in the assembly pathways. Monomers of the T antigens can form hexameric complexes solely upon incubation with ATP and Mg2+; in contrast, as we show here E1 must bind DNA in order to assemble as a hexamer. Similar observations have recently been reported by Sedman and Stenlund (48), who have shown that single strand DNA can initiate hexamer formation. That duplex DNA can also affect this multimerization fits nicely into a pathway through which the enhancer protein E2 helps target E1 to the ori site and once E2 frees itself from the preinitiation complex (27) double hexamers may readily follow at appropriate E1 concentrations.

These apparent biochemical differences may, however, be discussed in another way that brings the papillomaviruses' mode of DNA replication even closer to the SV40/polyoma family. For DNA replication in vivo both SV40 and polyoma large T antigens have enhancer sequences as cis-dominant elements and for polyoma virus these elements are absolutely required. Interestingly, the polyomavirus large T antigen can bind cooperatively with c-Jun, a factor naturally found to bind to polyoma DNA, and this targeting stimulates helicase activity (49). Furthermore, E2 can activate polyoma virus replication in the cell if E2 sites are engineered into viral vectors (50). Although it is perhaps too premature to speculate on the evolutionary pathway through which the genes encoding for these viral initiators descend, at least in part because we do not know how eukaryote chromosomal replication origins engage or assemble active helicases, it seems possible that the special relationship that E2 and E1 have with each other mimics cellular processes captured by the SV40/polyomavirus family.

Image Analysis of the Rings Reveals an Unexpected Heterogeneity-- Electron microscopy and image analysis have shown that the rings formed by the E1 protein are hexameric. However, the population of such rings formed in the presence of an oligonucleotide are not homogeneous, and two parameters of variability were observed. First, a subset of rings existed not as symmetric hexamers, but as trimers of dimers, generating a 3-fold rotational symmetry. This has previously been observed by electron microscopy for the hexameric rings formed by the dnaB protein (39, 45) and the RecA protein (51). It is likely that this structural dimerization correlates with the biochemical non-equivalence of subunits observed for other hexameric helicases. The T7 gp4 hexamer, for example, has been shown to contain only three, not six, high affinity ATP-binding sites (52), as has the hexameric rho protein (53) and DnaB (54).

Second, a large mass of density can exist in the central channel of the ring, and appears to not depend upon whether the ring has 6- or 3-fold symmetry. What gives rise to this density? We think it very unlikely that this density could arise from the oligonucleotide used to induce ring formation. One primary reason is that this mass appears too large to be due to the approximately 20-kDa mass of the oligonucleotide. The mass also appears to be continuously variable in its strength, an observation not compatible with it arising from the bound oligonucleotide. Also, since this oligonucleotide is required for ring formation, it is hard to explain the existence of rings without this density if the density is due to the oligonucleotide. Third, this mass appears to be found on the rotational axis of the rings (Fig. 8, b and d), while we would expect the density due to the oligonucleotide not only to be much smaller but asymmetrically displaced from the central axis (10). Based upon our experience imaging the T7 gp4 helicase with a bound oligonucleotide (10), the weak asymmetric density that is found within the central channel in the E1 rings shown in Fig. 8, a and c, is consistent with the density that we would expect from the oligonucleotide.

Since the preparation is at least 95% pure (as judged by SDS-PAGE), and plugged centers were observed for E1 purified from both E. coli and SF9 cells, and the density is too great to be due to the oligonucleotide, the most likely explanation is that this central density arises from a portion of the E1 protein. This density may therefore arise from a disordered or highly mobile domain of the E1 protein, that can exist in multiple conformations. The recent crystal structure of an E. coli helicase, the Rep protein (55), provides a possible clue in this regard. Two copies of Rep were observed in the crystal, and the two differed by a rotation of the 2B subdomain by 130°. Since all helicases, including papilloma E1, are highly likely to have a conserved structure (55, 56), the highly mobile subdomain in Rep provides support for the possibility that the variable central density in E1 may be due to the large movement of such a domain.

Observations of the related SV40 large T antigen helicase3 have also shown a similar, variable central density. It is noteworthy that a three-dimensional reconstruction of large T antigen with a hole in the center (37) only accounted for about 60% of the expected molecular volume, perhaps due to the fact that a portion of the subunit is mobile or disordered and not seen in the averaged reconstruction. A recent study also used electron microscopy to address the multimeric state of E1. Liu et al. (57) estimated from molecular volumes that E1 complexes on DNA are either hexameric or dihexameric. We did not find such size heterogeneity on DNA templates and it is possible that the hexamers observed by Liu et al. were actually intermediates or aggregates not detected in our experiments.

The Path of DNA through the Double Rings-- The electron microscopic images of E1 assembled on duplex DNA (Fig. 6) are consistent with the idea that the DNA somehow passes through the central cavities of the rings. Our end to end length measurements of the DNA fragments so engaged with the helicase do not indicate a shortening and as shown in Fig. 9 this data by itself would be consistent with two sorts of models for strand passage. In one model both strands might pass through the centers of the double hexamers as shown in Fig. 9A. In the presence of a single strand binding (SSB) protein and ATP unwinding might proceed either with the helicase working as a molecular motor translocating along the DNA and unwinding in opposite directions, or as a molecular pump denaturing the duplex and forcing it out through a central port. This class of models is the one that seems to fit most of the data gathered for the SV40 large T antigen. The DNase I and chemical protection data (obtained prior to SSB addition) argues in any case that both strands are protected. Moreover Dean et al. (58) have shown that preformed hexamers of large T antigen are inactive for unwinding of circular duplex DNA. We have made similar observations for the BPV-1 E1 protein (data not shown). These results would be consistent with models that required a topological link between the helicase ring and the circular DNA, and that stable hexamers once formed could not engage the circle.


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Fig. 9.   Models illustrating how hexameric helicases might engage DNA. A, two hexameric helicases assemble as rings topologically linked to DNA with both strands passing through their central cavities. Two possible modes of unwinding are shown. To the left, the helicases translocate away from each other along the DNA, leaving single-stranded DNA in their wake. On the right is a mode of unwinding in which the helicases remain in contact and the single strands are spooled out between the ring:ring interface. This arrangement has been proposed for SV40 large T antigen based on electron microscopy of T antigen-mediated DNA unwinding reactions and is analogous to the way in which E. coli RuvB assembles at Holliday junctions (38, 64, 65). For this case a mechanism for keeping the strands apart within the ring cavity must operate, for example, two binding sites for single strands (5' to 3' and 3' to 5'). B, an adaptation of the model mentioned above addressing the possibility that the helicases assemble on DNA with only a single strand passing through the central cavity of each ring. Note that in model B a shortening of the DNA may be anticipated, but this shortening is a function of the angle between the two rings, as well as the precise contour and width of the rings.

Curiously, preformed hexamers can displace single-stranded oligonucleotides annealed to circular single-stranded molecules (58).4 This result perhaps suggests that a hexameric ring might engage the single strand circle from an external binding site, track along the DNA and upon engaging a duplex region pass the other strand through the center of the ring upon cycles of helicase action. Faced with duplex DNA the hexamer may have no such entry and therefore a complex assembly process starting from monomers would create such possibilities for engagement. Such a model might predict a strand passage situation for duplex DNA as depicted in Fig. 9B. The electron microscopic data presented here would also be consistent with this notion. Considerable variation in lengths for melted or single-stranded DNA have been found, and the channels created between subunits of the hexamers could space a strand as close to its complement in this arrangement as in the situation wherein both strands passed through the center of the rings. (Compare the positions of the black dots in the cross-sections shown in Fig. 9, A and B.) In the model shown in Fig. 9B both single strands might be protected from DNase protection by positing that the external one is buried or wrapped in the channel. Gillette et al. (59) have concluded from their results of DNA protection experiments that E1 binding does produce one type of complex resulting in DNA distortions even in the absence of ATP. Thus protein binding and assembly of the hexamer around DNA may provide enough energy to allow for one cycle of denaturation. It is also possible that the initial complexes depicted in Fig. 9, A and B, are in some equilibrium with each other and SSB or ATP might be expected to change this distribution.

Studies with the hexameric replication helicases from E. coli and their T phages have shown that a single subunit contacts the single strand (at a given time) and that the other strand passes outside of the ring (10, 60). In models for helicase action, this internal strand might be passed from one subunit to the next in cycles of ATP hydrolysis. Thus an attraction of the model in Fig. 9B is that it would lead to a conserved mode of action for the animal viral DNA helicases and their prokaryote relatives.

    ACKNOWLEDGEMENTS

We thank Arne Stenlund for providing the E. coli expression system for E1, Seth Harris and James Berger for a critical reading of the manuscript, and Terri DeLuca for word processing.

    FOOTNOTES

* This work was supported by National Institutes of Health Grants CA42414 and CA30490 (to M. B.) and GM35269 (to E. H. E.).The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

§ Present address: Life Science Div., Lawrence Berkeley National Laboratory, Berkeley, CA 94720.

parallel To whom correspondence should be addressed. Fax: 510-643-6334; E-mail: mbotchan{at}uclink4.berkeley.edu.

The abbreviations used are: BPV, bovine papiloma virus; GST, glutathione S-transferase; DTT, dithiothreitol; SSB, single stranded-binding protein; PAGE, polyacrylamide gel electrophoresis.

2 C. Sanders, personal communication.

3 X. Yu and E. H. Egelman, unpublished data.

4 E. Fouts and M. R. Botchan, unpublished observations.

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Top
Abstract
Introduction
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