The unwinding of duplex regions in DNA by the simian virus 40 large tumor antigen-associated DNA helicase activity

The DNA helicase activity associated with purified simian virus 40 (SV40) large tumor (T) antigen has been examined. A variety of DNA substrates were used to characterize this ATP-dependent activity. Linear single-stranded M13 DNA containing short duplex regions at both ends was used to show that SV40 T antigen helicase displaced the short, annealed fragment by unwinding in a 3' to 5' direction. Three different partial duplex structures consisting of 71-, 343-, and 851-nucleotide long fragments annealed to M13 single-stranded circular DNA were used to show that SV40 T antigen can readily unwind short and long duplex regions with almost equal facility. ATP and MgCl2 were required for this reaction. With the exception of GTP, dGTP, and CTP, the other common nucleoside triphosphates substituted for ATP with varied efficiency, while adenosine 5'-O-(thiotriphosphate) was inactive. The T antigen helicase activity was also examined using completely duplex DNA fragments (approximately 300 base pairs) with or without the SV40 origin sequence as substrates. In reactions containing small amounts (0.6 ng) of DNA, the ATP-dependent unwinding of duplex DNA fragments occurred with no dependence on the origin sequence. This reaction was stimulated 5- to 6-fold by the addition of the Escherichia coli single-stranded DNA-binding protein. When competitor DNA was added so that the ratio of SV40 T antigen to DNA was reduced 1000-fold, only DNA fragments containing a functional SV40 origin of replication were unwound. This reaction was dependent on ATP, MgCl2, and a DNA-binding protein, and was stimulated by inorganic phosphate or creatine phosphate. The origin sequence requirements for the unwinding reaction were the same as those for replication (the 64-base pair sequence present at T antigen binding site 2). Thus, under specified conditions, only duplex DNA fragments containing an intact SV40 core origin were unwound. In contrast, unwinding of partially duplex segments of DNA flanked by single-stranded regions can occur with no sequence specificity.     

Simian virus 40 large T antigen untwists DNA at the origin of DNA replication.

Simian virus 40 large tumor antigen (SV40 T antigen) untwists DNA at the SV40 replication origin. In the presence of ATP, T antigen shifted the average linking number of an SV40 origin-containing plasmid topoisomer distribution. The loss of up to two helical turns was detected. The reaction required the presence of the 64-base pair core origin of replication containing T antigen DNA binding site II; binding site I had no effect on the untwisting reaction. The presence of human single-stranded DNA binding protein (SSB) slightly reduced the degree of untwisting in the presence of ATP. ATP hydrolysis was not required since untwisting occurred in the presence of nonhydrolyzable analogs of ATP. However, in the presence of a nonhydrolyzable analog of ATP, the requirement for the SV40 origin sequence was lost. The origin requirement for DNA untwisting was also lost in the absence of dithiothreitol. The origin-specific untwisting activity of T antigen is distinct from its DNA helicase activity, since helicase activity does not require the SV40 origin but does require ATP hydrolysis. The lack of a requirement for SSB or ATP hydrolysis and the reduction in the pitch of the DNA helix by just a few turns at the replication origin distinguishes this reaction from the T antigen-mediated DNA unwinding reaction, which results in the formation of a highly underwound DNA molecule. Untwisting occurred without a lag after the start of the reaction, whereas unwound DNA was first detected after a lag of 10 min. It is proposed that the formation of a multimeric T antigen complex containing untwisted DNA at the SV40 origin is a prerequisite for the initiation of DNA unwinding and replication.     

Topoisomerase I associates specifically with simian virus 40 large-T-antigen double hexamer-origin complexes

Topoisomerase I (topo I) is required for releasing torsional stress during simian virus 40 (SV40) DNA replication. Recently, it has been demonstrated that topo I participates in initiation of replication as well as in elongation. Although T antigen and topo I can bind to one another in vitro, there is no direct evidence that topo I is a component of the replication initiation complex. We demonstrate in this report that topo I associates with T-antigen double hexamers bound to SV40 origin DNA (T(DH)) but not to single hexamers. This association has the same nucleotide and DNA requirements as those for the formation of double hexamers on DNA. Interestingly, topo I prefers to bind to fully formed T(DH) complexes over other oligomerized forms of T antigen associated with the origin. High ratios of topo I to origin DNA destabilize T(DH). The partial unwinding of a small-circular-DNA substrate is dependent on the presence of both T antigen and topo I but is inhibited at high topo I concentrations. Competition experiments with a topo I-binding fragment of T antigen indicate that an interaction between T antigen and topo I occurs during the unwinding reaction. We propose that topo I is recruited to the initiation complex after the assembly of T(DH) and before unwinding to facilitate DNA replication.     

Only one of the origin binding forms of SV40 T antigen has helicase activity

SV40 T antigen exists in monomeric and multimeric forms. We have separated the individual components by glycerol gradient centrifugation. Helicase activity is found to be associated with monomeric forms only. Dimers and other multimeric forms have no discernable helicase activity. However, results obtained from DNA binding experiments carried out with separated forms of T antigen indicate that both monomers and dimers bind to region I and region II of SV40 origin of replication. Possibly monomeric T antigen unwinds DNA at the replication fork while both monomeric and dimeric forms are utilized for positioning of T antigen at the origin of replication.     

Preformed hexamers of SV40 T antigen are active in RNA and origin-DNA unwinding

Preformed hexamers of simian virus 40 (SV40) large tumor antigen (T antigen) constitute the bulk of T antigen in infected cells and are stable under physiological conditions. In spite of this they could not be assigned a function in virus replication or transformation. We report that preformed hexamers represent the active T antigen RNA helicase. Monomers and smaller oligomeric forms of T antigen were inactive due to the lack of hexamer formation under RNA unwinding conditions. In contrast to the immunologically related cellular DEAD-box protein p68, the T antigen RNA helicase is found to act in a much more processive way and it does not catalyze rearrangements of structured RNAs. Thereby, it rather seems to resemble other virus-encoded RNA helicases, like vaccinia virus NPH-II. Surprisingly, in our hands preformed hexamers also strikingly bound to and unwound the SV40 replication origin, pointing to a possible role of preformed hexamers in the initiation step of viral DNA replication. Furthermore, we have detected an extra hexamer-specific, high-affinity T antigen ATP binding site with a very slow exchange rate constant, the function of which is discussed.     

Large T antigen on the simian virus 40 origin of replication: a 3D snapshot prior to DNA replication

Large T antigen is the replicative helicase of simian virus 40. Its specific binding to the origin of replication and oligomerization into a double hexamer distorts and unwinds dsDNA. In viral replication, T antigen acts as a functional homolog of the eukaryotic minichromosome maintenance factor MCM. T antigen is also an oncoprotein involved in transformation through interaction with p53 and pRb. We obtained the three-dimensional structure of the full-length T antigen double hexamer assembled at its origin of replication by cryoelectron microscopy and single-particle reconstruction techniques. The double hexamer shows different degrees of bending along the DNA axis. The two hexamers are differentiated entities rotated relative to each other. Isolated strands of density, putatively assigned to ssDNA, protrude from the hexamer-hexamer junction mainly at two opposite sites. The structure of the T antigen at the origin of replication can be understood as a snapshot of the dynamic events leading to DNA unwinding. Based on these results a model for the initiation of simian virus 40 DNA replication is proposed.     

Mutation of the cyclin-dependent kinase phosphorylation site in simian virus 40 (SV40) large T antigen specifically blocks SV40 origin DNA unwinding.

A mutant simian virus 40 (SV40) large tumor (T) antigen bearing alanine instead of threonine at residue 124 (T124A) failed to replicate SV40 DNA in infected monkey cells (J. Schneider and E. Fanning, J. Virol. 62:1598-1605, 1988). We investigated the biochemical properties of T124A T antigen in greater detail by using purified protein from a baculovirus expression system. Purified T124A is defective in SV40 DNA replication in vitro, but does bind specifically to the viral origin under the conditions normally used for DNA replication. The mutant protein forms double-hexamer complexes at the origin in an ATP-dependent fashion, although the binding reaction requires somewhat higher protein concentrations than the wild-type protein. Binding of T124A protein results in local distortion of the origin DNA similar to that observed with the wild-type protein. These findings indicate that the replication defect of T124A protein is not due to failure to recognize and occupy the origin. Under some conditions T124A is capable of unwinding short origin DNA fragments. However, the mutant protein is almost completely defective in unwinding of circular plasmid DNA molecules containing the SV40 origin. Since the helicase activity of T124A is essentially identical to that of the wild-type protein, we conclude that the mutant is defective in the initial opening of the duplex at the origin, possibly as a result of altered hexamer-hexamer interactions. The phenotype of T124A suggests a possible role for phosphorylation of threonine 124 by cyclin-dependent kinases in controlling the origin unwinding activity of T antigen in infected cells.     

trans-Dominant and non-trans-dominant mutant simian virus 40 large T antigens show distinct responses to ATP.

Simian virus 40 (SV40) DNA replication requires the coordinated action of multiple biochemical activities intrinsic to the virus-encoded large tumor antigen (T antigen). We report the preliminary biochemical characterization of the T antigens encoded by three SV40 mutants, 5030, 5031, and 5061, each of which have altered residues within or near the ATP binding pocket. All three mutants are defective for viral DNA replication in cultured cell lines. However, while 5030 and 5031 can be complemented in vivo by providing a wild-type T antigen in trans, 5061 exhibits a strong trans-dominant-negative phenotype. In order to determine the basis for their replication defects and to explore the mechanisms of trans dominance, we purified the T antigens encoded by each of these mutants and examined their activities in vitro. The 5061 T antigen had no measurable ATPase activity and failed to hexamerize in response to ATP, and its affinity for the SV40 origin of DNA replication (ori) DNA was not increased by ATP. In contrast, the 5030 and 5031 T antigens exhibited at least some ATPase activity and both readily formed hexamers in the presence of ATP. These mutants differed in that 5030 was very defective in an ori-dependent unwinding assay while 5031 retained significant activity. Both the 5030 and 5031 T antigens bound to ori-containing DNA, but the binding was less efficient than that of wild-type T antigen and was not affected by the presence of ATP. These results suggest that 5030 and 5031 are defective in some aspect of communication between the ATP binding and DNA binding domains and that the ability of ATP to induce T-antigen hexamerization is distinct from its action to increase the affinity for ori. Finally, all three mutants were defective for the ability to support SV40 DNA replication in vitro. Both the 5031 and 5061 T antigens inhibited wild-type-T-antigen-stimulated replication in vitro, while the 5030 T antigen did not. The fact that the 5031 T antigen was trans dominant in the in vitro assays but not in vivo indicates that the in vitro system does not accurately reflect events occurring in vivo.     

Phosphorylation of simian virus 40 T antigen on Thr 124 selectively promotes double-hexamer formation on subfragments of the viral core origin

Cell cycle-dependent phosphorylation of simian virus 40 (SV40) large tumor antigen (T-ag) on threonine 124 is essential for the initiation of viral DNA replication. A T-ag molecule containing a Thr-->Ala substitution at this position (T124A) was previously shown to bind to the SV40 core origin but to be defective in DNA unwinding and initiation of DNA replication. However, exactly what step in the initiation process is defective as a result of the T124A mutation has not been established. Therefore, to better understand the control of SV40 replication, we have reinvestigated the assembly of T124A molecules on the SV40 origin. Herein it is demonstrated that hexamer formation is unaffected by the phosphorylation state of Thr 124. In contrast, T124A molecules are defective in double-hexamer assembly on subfragments of the core origin containing single assembly units. We also report that T124A molecules are inhibitors of T-ag double hexamer formation. These and related studies indicate that phosphorylation of T-ag on Thr 124 is a necessary step for completing the assembly of functional double hexamers on the SV40 origin. The implications of these studies for the cell cycle control of SV40 DNA replication are discussed.     

DNA helicase and duplex DNA fragment unwinding activities of polyoma and simian virus 40 large T antigen display similarities and differences.

We have characterized the biochemical activities of purified polyoma (Py) large T antigen (T Ag) that was capable of mediating the replication of a plasmid containing the Py origin (ori(+) DNA) in mouse cell extracts. We report here that like the T Ag encoded by simian virus 40 (SV40), Py T Ag has DNA helicase and double-stranded DNA fragment unwinding activities. Py T Ag displaced DNA fragments greater than 1,600 nucleotides which were annealed to complementary sequences in single-stranded M13 by translocating in the 3' to 5' direction. Both helicase and double-stranded DNA fragment unwinding reactions were completely dependent upon NTP hydrolysis, displaying a strong preference for ATP and dATP. At low T Ag concentrations, significantly more Py ori(+) DNA fragment was unwound compared with a fragment lacking the replication origin. However, at higher ratios of Py T Ag to DNA, equivalent to those used in replication reactions, unwinding of both ori-containing and -lacking fragments was equally efficient. This is in contrast to SV40 T Ag which exhibited a more stringent requirement for SV40 origin sequences under similar conditions. Furthermore, some of the nucleotides that supported the helicase and unwinding activities of Py T Ag were different from those for the same SV40 T Ag reactions. We have also observed that in contrast to the very poor replication of linear SV40 ori(+) DNA by SV40 T Ag in human cell extracts, linear Py ori(+) DNA was replicated efficiently in mouse cell extracts by Py T Ag. However, despite the fact that linear Py ori(+), SV40 ori(+), and ori(-) DNA fragments could be unwound with comparable efficiency by Py T Ag, only fragments containing the Py replication origin were replicated in vitro. These results suggest that the initiation of DNA synthesis at the Py origin of replication requires features in addition to unwinding of the template.     

Mechanisms of simian virus 40 T-antigen activation by phosphorylation of threonine 124.

Previous studies have shown that phosphorylation of simian virus 40 (SV40) T antigen at threonine 124 enhances the binding of T antigen to the SV40 core origin of replication and the unwinding of the core origin DNA via hexamer-hexamer interactions. Here, we report that threonine 124 phosphorylation enhances the interaction of T-antigen amino acids 1 to 259 and 89 to 259 with the core origin of replication. Phosphorylation, therefore, activates the minimal DNA binding domain of T antigen even in the absence of domains required for hexamer formation. Activation is mediated by only one of three DNA binding elements in the minimal DNA binding domain of T antigen. This element, including amino acids 167, 215, and 219, enhances binding to the unique arrangement of four pentanucleotides in the core origin but not to other pentanucleotide arrangements found in ancillary regions of the SV40 origin of replication. Interestingly, the same four pentanucleotides in the core origin are necessary and sufficient for phosphorylation-enhanced DNA binding. Further, we show that phosphorylation of threonine 124 promotes the assembly of high-order complexes of the minimal DNA binding domain of T antigen with core origin DNA. We propose that phosphorylation induces conformational shifts in the minimal DNA binding domain of T antigen and thereby enhances interactions among T-antigen subunits oriented by core origin pentanucleotides. Similar subunit interactions would enhance both assembly of full-length T antigen into binary hexamer complexes and origin unwinding.     

Role of single-stranded DNA binding activity of T antigen in simian virus 40 DNA replication

We have previously mapped the single-stranded DNA binding domain of large T antigen to amino acid residues 259 to 627. By using internal deletion mutants, we show that this domain most likely begins after residue 301 and that the region between residues 501 and 550 is not required. To study the function of this binding activity, a series of single-point substitutions were introduced in this domain, and the mutants were tested for their ability to support simian virus 40 (SV40) replication and to bind to single-stranded DNA. Two replication-defective mutants (429DA and 460EA) were grossly impaired in single-stranded DNA binding. These two mutants were further tested for other biochemical activities needed for viral DNA replication. They bound to origin DNA and formed double hexamers in the presence of ATP. Their ability to unwind origin DNA and a helicase substrate was severely reduced, although they still had ATPase activity. These results suggest that the single-stranded DNA binding activity is involved in DNA unwinding. The two mutants were also very defective in structural distortion of origin DNA, making it likely that single-stranded DNA binding is also required for this process. These data show that single-stranded DNA binding is needed for at least two steps during SV40 DNA replication.     

Differential induction of structural changes in the simian virus 40 origin of replication by T antigen.

The ATP-dependent binding of the simian virus 40 (SV40) large tumor antigen (T antigen) to the SV40 origin of replication (ori) results in the structural distortion of two critical elements within flanking regions of ori and the untwisting of the DNA helix. We examined the effect of changes in temperature, ATP concentration, and other reaction parameters on the generation of these DNA structural changes. We found that induction of the two localized structural transitions were highly and differentially sensitive to reaction conditions. Significant distortion of the early palindrome element, shown previously to result from DNA melting, required low levels of ATP (10 to 30 microM) but temperatures above 25 degrees C. Distortion of the AT tract occurred at low temperatures (5 degrees C) but required relatively high concentrations of ATP (greater than 300 microM). Thus, T antigen can induce structural changes within one critical element of ori without generating significant structural distortion within the second element. The response of ori untwisting to reaction conditions generally increased in parallel with or fell intermediate between the inductions of localized structural transitions. We suggest that ori untwisting and localized structural distortions are interdependent consequences of T-antigen binding to ori. These results suggest a model for the structural events occurring during the initial steps of SV40 DNA replication.     

Simian virus 40 T-antigen DNA helicase is a hexamer which forms a binary complex during bidirectional unwinding from the viral origin of DNA replication.

The role of simian virus 40 (SV40) large tumor antigen (T antigen) as a DNA helicase at the replication fork was studied. We found that a T-antigen hexamer complex acts during the unidirectional unwinding of appropriate DNA substrates and is localized directly in the center of the fork, contacting the adjacent double strand as well as the emerging single strands. When bidirectional DNA unwinding, initiated at the viral origin of DNA replication, was analyzed, a larger T-antigen complex that is simultaneously active at both branch points of an unwinding bubble was observed. The size and shape of this helicase complex imply that the T-antigen dodecamer complex, assembled at the origin and active in the localized melting of duplex DNA, is subsequently also used to continue DNA unwinding bidirectionally. Then, however, the dodecamer complex does not split into two hexamer subunits that track along the DNA; rather, the DNA is threaded through the intact complex, with the concomitant extrusion of single-stranded loops.     

Simian virus 40 DNA replication in vitro: identification of multiple stages of initiation.

A cell-free DNA replication system dependent upon five purified cellular proteins, one crude cellular fraction, and the simian virus 40 (SV40)-encoded large tumor antigen (T antigen) initiated and completed replication of plasmids containing the SV40 origin sequence. DNA synthesis initiated at or near the origin sequence after a time lag of approximately 10 min and then proceeded bidirectionally from the origin to yield covalently closed, monomer daughter molecules. The time lag could be completely eliminated by a preincubation of SV40 ori DNA in the presence of T antigen, a eucaryotic single-stranded DNA-binding protein (replication factor A [RF-A]), and topoisomerases I and II. In contrast, if T antigen and the template DNA were incubated alone, the time lag was only partially decreased. Kinetic analyses of origin recognition by T antigen, origin unwinding, and DNA synthesis suggest that the time lag in replication was due to the formation of a complex between T antigen and DNA called the T complex, followed by formation of a second complex called the unwound complex. Formation of the unwound complex required RF-A. When origin unwinding was coupled to DNA replication by the addition of a partially purified cellular fraction (IIA), DNA synthesis initiated at the ori sequence, but the template DNA was not completely replicated. Complete DNA replication in this system required the proliferating-cell nuclear antigen and another cellular replication factor, RF-C, during the elongation stage. In a less fractionated system, another cellular fraction, SSI, was previously shown to be necessary for reconstitution of DNA replication. The SSI fraction was required in the less purified system to antagonize the inhibitory action of another cellular protein(s). This inhibitor specifically blocked the earliest stage of DNA replication, but not the later stages. The implications of these results for the mechanisms of initiation and elongation of DNA replication are discussed.     

Mechanisms of conformational change for a replicative hexameric helicase of SV40 large tumor antigen

The large tumor antigen (LTag) of simian virus 40, an AAA(+) protein, is a hexameric helicase essential for viral DNA replication in eukaryotic cells. LTag functions as an efficient molecular machine powered by ATP binding and hydrolysis for origin DNA melting and replication fork unwinding. To understand how ATP binding and hydrolysis are coupled to conformational changes, we have determined high-resolution structures ( approximately 1.9 A) of LTag hexamers in distinct nucleotide binding states. The structural differences of LTag in various nucleotide states detail the molecular mechanisms of conformational changes triggered by ATP binding/hydrolysis and reveal a potential mechanism of concerted nucleotide binding and hydrolysis. During these conformational changes, the angles and orientations between domains of a monomer alter, creating an "iris"-like motion in the hexamer. Additionally, six unique beta hairpins on the channel surface move longitudinally along the central channel, possibly serving as a motor for pulling DNA into the LTag double hexamer for unwinding.     

Conformational Rearrangements of SV40 Large T Antigen during Early Replication Events

The Simian virus 40 (SV40) large tumor antigen (LTag) functions as the replicative helicase and initiator for viral DNA replication. For SV40 replication, the first essential step is the assembly of an LTag double hexamer at the origin DNA that will subsequently melt the origin DNA to initiate fork unwinding. In this study, we used three-dimensional cryo-electron microscopy to visualize early events in the activation of DNA replication in the SV40 model system. We obtained structures of wild-type double-hexamer complexes of LTag bound to SV40 origin DNA, to which atomic structures have been fitted. Wild-type LTag was observed in two distinct conformations: In one conformation, the central module containing the J-domains and the origin binding domains of both hexamers is a compact closed ring. In the other conformation, the central module is an open ring with a gap formed by rearrangement of the N-terminal regions of the two hexamers, potentially allowing for the passage of single-stranded DNA generated from the melted origin DNA. Double-hexamer complexes containing mutant LTag that lacks the N-terminal J-domain show the central module predominantly in the closed-ring state. Analyses of the LTag C-terminal regions reveal that the LTag hexamers bound to the A/T-rich tract origin of replication and early palindrome origin of replication elements are structurally distinct. Lastly, visualization of DNA density protruding from the LTag C-terminal domains suggests that oligomerization of the LTag complex takes place on double-stranded DNA.     

Re-oxygenation of hypoxic simian virus 40 (SV40)-infected CV1 cells causes distinct changes of SV40 minichromosome-associated replication proteins.

Hypoxia interrupts the initiation of simian virus 40 (SV40) replication in vivo at a stage situated before unwinding of the origin region. After re-oxygenation, unwinding followed by a synchronous round of viral replication takes place. To further characterize the hypoxia-induced inhibition of unwinding, we analysed the binding of several replication proteins to the viral minichromosome before and after re-oxygenation. T antigen, the 34-kDa subunit of replication protein A (RPA), topoisomerase I, the 48-kDa subunit of primase, the 125-kDa subunit of polymerase delta, and the 37-kDa subunit of replication factor C (RFC) were present at the viral chromatin already under hypoxia. The 70-kDa subunit of RPA, the 180-kDa subunit of polymerase alpha, and proliferating cell nuclear antigen (PCNA) were barely detectable at the SV40 chromatin under hypoxia and significantly increased after re-oxygenation. Immunoprecipitation of minichromosomes with T antigen-specific antibody and subsequent digestion with micrococcus nuclease revealed that most of the minichromosome-bound T antigen was associated with the viral origin in hypoxic and in re-oxygenated cells. T antigen-catalysed unwinding of the SV40 origin occurred, however, only after re-oxygenation as indicated by (a) increased sensitivity of re-oxygenated minichromosomes against digestion with single-stranded DNA-specific nuclease P1; (b) stabilization of RPA-34 binding at the SV40 minichromosome; and (c) additional phosphorylations of RPA-34 after re-oxygenation, probably catalysed by DNA-dependent protein kinase. The results presented suggest that the subunits of the proteins necessary for unwinding, primer synthesis and primer elongation first assemble at the SV40 origin in form of stable, active complexes directly before they start to work.     

Sequence independent duplex DNA opening reaction catalysed by SV40 large tumor antigen.

Simian virus 40 (SV40) large tumor antigen (T antigen) is mainly localized in the nucleus where it exhibits two biochemical properties: DNA binding and helicase activity. Both activities are necessary for viral DNA replication and may also enable T antigen to modulate cellular growth. Here we present biochemical and electron microscopic evidence that the helicase activity can start at internal sites of fully double-stranded DNA molecules not containing the SV40 origin or replication. Using T antigen specific monoclonal antibodies, this unwinding reaction can be biochemically divided in an initiation (duplex opening) and a propagation step. The duplex opening reaction (as well as the propagation step) does not depend on a specific DNA sequence or secondary structure. In addition, we have found that T antigen forms an ATP dependent nucleoprotein complex at double-stranded DNA, which may be an essential step for the sequence independent duplex DNA opening reaction.     

Large T-antigen double hexamers imaged at the simian virus 40 origin of replication

The initial step of simian virus 40 (SV40) DNA replication is the binding of the large tumor antigen (T-Ag) to the SV40 core origin. In the presence of Mg(2+) and ATP, T-Ag forms a double-hexamer complex covering the complete core origin. By using electron microscopy and negative staining, we visualized for the first time T-Ag double hexamers bound to the SV40 origin. Image processing of side views of these nucleoprotein complexes revealed bilobed particles 24 nm long and 8 to 12 nm wide, which indicates that the two T-Ag hexamers are oriented head to head. Taking into account all of the biochemical data known on the T-Ag-DNA interactions at the replication origin, we present a model in which the DNA passes through the inner channel of both hexamers. In addition, we describe a previously undetected structural domain of the T-Ag hexamer and thereby amend the previously published dimensions of the T-Ag hexamer. This domain we have determined to be the DNA-binding domain of T-Ag.