The DNA-binding properties of polyomavirus large T antigen are altered by ATP and other nucleotides.

We have examined the influence of ATP on the DNA-binding properties of polyomavirus large T antigen (Py TAg). Utilizing nitrocellulose filter binding, DNase I footprinting, and gel mobility shift assays, we observed that ATP increased Py TAg binding to DNA fragments containing either all Py TAg-binding sites (whole origin) or those sites within (core origin) or adjacent to (early) the origin of replication. Even nonspecific binding to DNA fragments lacking Py TAg-binding sites was increased somewhat by ATP. Binding to the core origin was increased to a greater extent than binding to other DNA fragments tested. Gel band mobility shift assays revealed that ATP increased the production of core origin-specific Py TAg-DNA complexes of high molecular weight. ATP stimulation depended on the presence of MgCl2. Other nucleotides and nonhydrolyzable ATP analogs also increased Py TAg binding to the core origin but to various degrees: ATP, dATP, 5'-adenylyl imidodiphosphate (AMPPNP) greater than 5'-adenylyl methylenediphosphate (AMPPCP) greater than dCTP greater than UTP greater than TTP. GTP and dGTP did not increase DNA binding by Py TAg. The rates of association and disassociation of Py TAg with all the DNA fragments were altered by the presence of ATP. DNase I footprinting showed that ATP extensively extended the region protected within the core origin and also produced a distinctive DNase I-hypersensitive site on the late strand at nucleotides 5255 to 5262 (TTACTATG).     

The simian virus 40 T antigen double hexamer assembles around the DNA at the replication origin.

An initial step in the replication of simian virus (SV40) DNA is the ATP-dependent formation of a double hexamer of the SV40 large tumor (T) antigen at the SV40 DNA replication origin. In the absence of DNA, T antigen assembled into hexamers in the presence of magnesium and ATP. Hexameric T antigen was stable and could be isolated by glycerol gradient centrifugation. The ATPase activities of hexameric and monomeric T antigen isolated from parallel glycerol gradients were identical. However, while monomeric T antigen was active in the ATP-dependent binding, untwisting, unwinding, and replication of SV40 origin-containing DNA, hexameric T antigen was inactive in these reactions. Isolated hexamers incubated at 37 degrees C in the presence of ATP remained intact, but dissociated into monomers when incubated at 37 degrees C in the absence of ATP. This dissociation restored the activity of these preparations in the DNA replication reaction, indicating that hexameric T antigen is not permanently inactivated but merely assembled into a nonproductive structure. We propose that the two hexamers of T antigen at the SV40 origin assemble around the DNA from monomer T antigen in solution. This complex untwists the DNA at the origin, melting specific DNA sequences. The resulting single-stranded regions may be utilized by the T antigen helicase activity to initiate DNA unwinding bidirectionally from the origin.     

ATP enhances the binding of simian virus 40 large T antigen to the origin of replication.

Simian virus 40 large T antigen initiates DNA replication by binding to the origin of replication. We examined the binding of T antigen to origin regions I, II, and III under conditions designed for efficient in vitro replication functions. We found that 4 mM ATP enhanced the binding of T antigen to regions I and II of the origin DNA by 4- to 20-fold. DNase-footprinting and fragment assays showed that ATP extended the DNase protection domain of T antigen bound to region II by 5 to 10 base pairs at both ends of the core origin of replication. This alteration suggests a change in the conformation of T antigen, bound DNA, or both.     

Application of an immunoprecipitation procedure to the study of SV40 tumor antigen interaction with mouse genomic DNA sequences.

Simian Virus 40 (SV40) large T antigen is a DNA binding protein with high affinity for segments of the viral genome. To find out whether T antigen also binds to sequences of genomic cellular DNA we mixed T antigen and SAU 3 A restricted mouse DNA under stringent DNA binding conditions. Resulting protein-DNA complexes were immunoprecipitated using T antigen specific monoclonal or polyclonal antibodies. The DNA fragments in the immunoprecipitates were cloned in plasmid vectors. Four plasmid clones were selected for a detailed investigation of the inserted mouse DNA fragments. Nucleotide sequencing and DNase I footprint experiments showed that T antigen binds to sites in these fragments consisting of two tandemly oriented G(A)AGGC pentamers separated by AT rich spacers of different lengths. The cellular binding sites are very similar in their architecture to the SV40-DNA binding site I. The isolated cellular DNA fragments with T antigen binding sites occur only once or a few times in the mouse genome. Our data help to further define the structure of T antigen's DNA binding sites. The genetic functions of the isolated cellular DNA elements are not known.     

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.     

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.     

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.     

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.     

The NS1 polypeptide of the murine parvovirus minute virus of mice binds to DNA sequences containing the motif [ACCA]2-3.

A DNA fragment containing the minute virus of mice 3' replication origin was specifically coprecipitated in immune complexes containing the virally coded NS1, but not the NS2, polypeptide. Antibodies directed against the amino- or carboxy-terminal regions of NS1 precipitated the NS1-origin complexes, but antibodies directed against NS1 amino acids 284 to 459 blocked complex formation. Using affinity-purified histidine-tagged NS1 preparations, we have shown that the specific protein-DNA interaction is of moderate affinity, being stable in 0.1 M salt but rapidly lost at higher salt concentrations. In contrast, generalized (or nonspecific) DNA binding by NS1 could be demonstrated only in low salt. Addition of ATP or gamma S-ATP enhanced specific DNA binding by wild-type NS1 severalfold, but binding was lost under conditions which favored ATP hydrolysis. NS1 molecules with mutations in a critical lysine residue (amino acid 405) in the consensus ATP-binding site bound to the origin, but this binding could not be enhanced by ATP addition. DNase I protection assays carried out with wild-type NS1 in the presence of gamma S-ATP gave footprints which extended over 43 nucleotides on both DNA strands, from the middle of the origin bubble sequence to a position some 14 bp beyond the nick site. The DNA-binding site for NS1 was mapped to a 22-bp fragment from the middle of the 3' replication origin which contains the sequence ACCAACCA. This conforms to a reiterated motif (ACCA)2-3, which occurs, in more or less degenerate form, at many sites throughout the minute virus of mice genome (J. W. Bodner, Virus Genes 2:167-182, 1989). Insertion of a single copy of the sequence (ACCA)3 was shown to be sufficient to confer NS1 binding on an otherwise unrecognized plasmid fragment. The functions of NS1 in the viral life cycle are reevaluated in the light of this result.     

Mutational analysis of simian virus 40 large T antigen DNA binding sites.

We have tested the effects of various mutations within SV40 T antigen DNA recognition sites I and II on specific T antigen binding using the DNase footprint technique. In addition, the replication of plasmid DNA templates carrying these T antigen binding site mutations was monitored by Southern analysis of transfected DNA in COS cells. Deletion mapping of site I sequences defined a central core of approximately 18 bp that is both necessary and sufficient for T antigen recognition; this region contains the site I contact nucleotides that were previously mapped using methylation-interference and methylation-protection experiments. A similar deletion analysis delineated sequences that impart specificity of binding to site II. We find that T antigen is capable of specific recognition of site II in the absence of site I sequences, indicating that binding to site II in vitro is not dependent on binding of T antigen at site I. Site II binding was not diminished by small deletion or substitution mutations that perturb the 27-bp palindrome central to binding site II, whereas extensive substitution of site II sequences completely eliminated specific site II binding. Analysis of the replication in COS7 cells of plasmids that contain these mutant origins revealed that sequences both at the late side of binding site I and within the site II palindrome are crucial for viral DNA replication, but are not involved in binding T antigen.     

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.     

The zinc finger region of simian virus 40 large T antigen is needed for hexamer assembly and origin melting.

Simian virus 40 large T antigen contains a single sequence element with an arrangement of cysteines and histidines that is characteristic of a zinc finger motif. The finger region maps from amino acids 302 through 320 and has the sequence C-302 L K C-305 I K K E Q P S H Y K Y H-317 E K H-320. Previous genetic analysis has shown that the cysteine and histidine sequences and the contiguous S H Y K Y region in the finger are important for DNA replication in vivo. We show here that representative mutations in either of these elements of the finger prevent the assembly of large T antigen into stable hexamers in vitro. These same mutations have a characteristic effect on the interaction of T antigen with the simian virus 40 core origin of replication. The mutant T antigens bind to the central pentanucleotide domain of the core origin but fail to melt the adjacent inverted repeat domain and to untwist the adenine-thymine domain. These defects would prevent the formation of a replication bubble and the initiation of DNA replication. Finger mutations have lesser effects on the helicase function of T antigen and no observable effect on binding of T antigen to the mouse p53 protein. We propose that the zinc finger region contributes to protein-protein interactions essential for the assembly of stable T-antigen hexamers at the origin of replication and that hexamers are needed for subsequent alterations in the structure of origin DNA. We cannot exclude the possibility that the zinc finger region also makes specific contacts with components of origin DNA.     

The Replication Protein A Binding Site in Simian Virus 40 (SV40) T Antigen and Its Role in the Initial Steps of SV40 DNA Replication

Physical interactions of simian virus 40 (SV40) large tumor (T) antigen with cellular DNA polymerase α-primase (Pol/Prim) and replication protein A (RPA) appear to be responsible for multiple functional interactions among these proteins that are required for initiation of viral DNA replication at the origin, as well as during lagging-strand synthesis. In this study, we mapped an RPA binding site in T antigen (residues 164 to 249) that is embedded within the DNA binding domain of T antigen. Two monoclonal antibodies whose epitopes map within this region specifically interfered with RPA binding to T antigen but did not affect T-antigen binding to origin DNA or Pol/Prim, ATPase, or DNA helicase activity and had only a modest effect on origin DNA unwinding, suggesting that they could be used to test the functional importance of this RPA binding site in the initiation of viral DNA replication. To rule out a possible effect of these antibodies on origin DNA unwinding, we used a two-step initiation reaction in which an underwound template was first generated in the absence of primer synthesis. In the second step, primer synthesis was monitored with or without the antibodies. Alternatively, an underwound primed template was formed in the first step, and primer elongation was tested with or without antibodies in the second step. The results show that the antibodies specifically inhibited both primer synthesis and primer elongation, demonstrating that this RPA binding site in T antigen plays an essential role in both events.     

Origin binding by a 100,000-dalton super-T antigen from SVT2 cells.

The SVT2 line of simian virus 40-transformed mouse cells expresses little or no wild-type-size A protein (T antigen). Instead, a variant form is produced in these cells that is larger than normal-size A protein. This variant form has an Mr of 100,000 (100K super-T antigen) and is found primarily in complexes with the host-cell-coded p53 protein. Binding of the 100K super-T antigen to simian virus 40 origin region DNA was assayed by immunoprecipitation of super-T antigen-DNA complexes and then digestion with DNase I. DNA sequences associated with super-T antigen were protected from digestion and retained in the immune complex, while unprotected sequences were digested and released. The 100K super-T antigen efficiently protects DNA sequences in the previously defined regions I and II (P. Tegtmeyer, B. A. Lewton, A. L. DeLucia, V. G. Wilson, and K. Ryder, J. Virol. 46:151-161, 1983). Within region II (the origin of replication), the pattern and size of protected fragments are identical for super-T antigen and purified wild-type A protein. Thus, even though super-T antigen is larger than wild-type A protein, both must bind with the same alignment on origin DNA. Furthermore, complexes between the host-cell-coded p53 protein and the 100K super-T antigen also retain the ability to bind in regions I and II.     

Interactions required for binding of simian virus 40 T antigen to the viral origin and molecular modeling of initial assembly events

The purified T-antigen origin binding domain binds site specifically to site II, the central region of the simian virus 40 core origin. However, in the context of full-length T antigen, the origin binding domain interacts poorly with DNA molecules containing just site II. Here we investigate the contributions of additional core origin regions, termed the flanking sequences, to origin recognition and the assembly of T-antigen hexamers and double hexamers. Results from these studies indicate that in addition to site-specific binding of the T-antigen origin binding domain to site II, T-antigen assembly requires non-sequence-specific interactions between a basic finger in the helicase domain and particular flanking sequences. Related studies demonstrate that the assembly of individual hexamers is coupled to the distortions in the proximal flanking sequence. In addition, the point in the double-hexamer assembly process that is regulated by phosphorylation of threonine 124, the sole posttranslational modification required for initiation of DNA replication, was further analyzed. Finally, T-antigen structural information is used to model various stages of T-antigen assembly on the core origin and the regulation of this process.     

A small subclass of SV40 T antigen binds to the viral origin of replication

We examined the affinities of SV40 large T antigen for unique viral DNA sequences by binding SV40 Bst NI DNA fragments in extracts of infected or transformed cells, and then immunoprecipitating the T antigen-DNA complex. The G fragment, which spans the viral origin of replication (ori) was quantitatively bound to T antigen. A T-antigen-specific monoclonal antibody (McI 7), which recognized only 5%-10% of the T antigen from infected or transformed cells, immunoprecipitated the majority of the ori-binding activity. This suggests that only a minor subclass of wild-type T antigen is active in binding to the origin. C6 cells contain a replication-defective mutant T antigen that when tested in the DNA-binding immunoassay, showed no affinity for the ori fragment. McI 7 not only failed to immunoprecipitate ori binding in C6 cells, but also did not detect any labeled C6 T antigen whatever. Thus McI 7 recognizes an immunologically distinct subset of wild-type 7 antigen that comprises the origin-binding form of the viral protein, which is absent in the C6 T antigen population. McI 122, which recognizes a 53 kilodalton host protein that complexes with T antigen, immunoprecipitated ori-binding activity from extracts of infected or transformed cells, but not from C6 cells. Thus wild-type T antigen can bind ori sequences even when complexed to the host protein. These data suggest that T antigen consists of different subpopulations with different functions.     

Synthetic DNA Replication Bubbles Bound and Unwound with Twofold Symmetry by a Simian Virus 40 T-Antigen Double Hexamer

Dimerization of simian virus 40 T-antigen hexamers (TAg_H) into double hexamers (TAg_DH) on model DNA replication forks has been found to greatly stimulate T-antigen DNA helicase activity. To explore the interaction of TAg_DH with DNA during unwinding, we examined the binding of TAg_DH to synthetic DNA replication bubbles. Tests of replication bubble substrates containing different single-stranded DNA (ssDNA) lengths indicated that efficient formation of a TAg_DH requires ≥40 nucleotides (nt) of ssDNA. DNase I probing of a substrate containing a 60-nt ssDNA bubble complexed with a TAg_DH revealed that T antigen bound the substrate with twofold symmetry. The strongest protection was observed over the 5′ junction on each strand, with 5 bp of duplex DNA and ~17 nt of adjacent ssDNA protected from nuclease cleavage. Stimulation of the T-antigen DNA helicase activity by an increase in ATP concentration caused the protection to extend in the 5′ direction into the duplex region, while resulting in no significant changes to the 3′ edge of strongest protection. Our data indicate that each TAg_H encircles one ssDNA strand, with a different strand bound at each junction. The process of DNA unwinding results in each TAg_H interacting with a greater length of DNA than was initially bound, suggesting the generation of a more highly processive helicase complex.     

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.     

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.