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.     

Constitutive expression of simian virus 40 large T antigen in monkey cells activates their capacity to support polyomavirus replication.

Polyomavirus DNA replication is normally restricted to rodent cells, and simian virus 40 (SV40) DNA replication is restricted to primate cells. We demonstrate that DNAs containing the polyomavirus origin can be replicated in monkey cells which constitutively express SV40 large T antigen. Permissivity is most likely caused by SV40 T antigen modification of cellular protein(s) required to replicate the polyomavirus origin. A possible target for the T-antigen-induced modification is DNA polymerase alpha-DNA primase.     

Functional implications of oligomerization of simian virus 40 large T antigen during lytic virus infection.

The formation of oligomers of simian virus 40 (SV40) large T antigen in SV40-infected and -transformed monkey cells was analyzed by sucrose density gradient centrifugation. The overall distribution of total T antigen during lytic infection showed mainly low-molecular-weight forms (monomers and dimers) in the early phase (10 h postinfection) and an increase in the number of oligomers in the late phase of the lytic cycle (36 h postinfection), indicating an accumulation of these final products. In contrast, studying the conversion of newly synthesized T antigen into oligomers by appropriate pulse-chase radiolabeling of infected cells revealed that this processing decelerates considerably during the late phase of infection. This mechanism can be reaccelerated by blocking DNA replication with aphidicolin. Since none of these results could be obtained by using synchronized SV40-transformed monkey cells (COS-1), these observations are compatible with the idea that the process of T antigen oligomerization may be involved in viral, but not in cellular, DNA synthesis.     

Monoclonal antibodies as probes for a function of large T antigen during the elongation process of simian virus 40 DNA replication.

Various monoclonal antibodies specific for simian virus 40 large tumor antigen (T antigen) inhibit the elongation process of viral DNA replication in an in vitro system. The results provide strong evidence for a function intrinsic to T antigen during ongoing replicative-chain elongation. The antibody inhibition studies were further used to establish a correlation between the known biochemical activities of T antigen and its function during the elongation phase. The data demonstrate that, in addition to DNA binding and ATPase, a third function of T antigen is required for replicative chain elongation. This function is most probably related to the recently described DNA helicase activity of T antigen. This conclusion is based on the following results: aphidicolin treatment of actively replicating simian virus 40 minichromosomes causes a partial uncoupling of parental DNA strand separation and DNA synthesis; the strand separation reaction is blocked by the same monoclonal antibodies which strongly inhibit the elongation process. DNA helicase activity of isolated T antigen is equally well inhibited by the same set of monoclonal antibodies that affect minichromosome replication in vitro.     

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.     

Mapping the transcriptional transactivation function of simian virus 40 large T antigen

T antigen is able to transactivate gene expression from the simian virus 40 (SV40) late promoter and from several other viral and cellular promoters. Neither the mechanisms of transactivation by T antigen nor the regions of T antigen required for this activity have been determined. To address the latter point, we have measured the ability of a set of SV40 large T antigen mutants to stimulate gene expression in CV-1 monkey kidney cells from the SV40 late promoter and Rous sarcoma virus (RSV) long terminal repeat (LTR) promoter. Transactivation, although reduced, was retained by an N-terminal 138-amino-acid fragment of T antigen. Mutants with alterations at various locations within the N-terminal 85 amino acids transactivated the RSV LTR promoter less well than did wild-type T antigen. Most of these were also partially defective in their ability to transactivate the SV40 late promoter. Two mutants with lesions in the DNA-binding domain that were unable to bind to SV40 DNA were completely defective for transactivation of both promoter, while a third mutant with a lesion in the DNA-binding domain which retained origin-binding activity transactivated both promoters as well as did wild-type T antigen. Only a low level of transactivation was seen with mutant T antigens which had lesions in or near the zinc finger region (amino acids 300 to 350). Mutations which caused defects in ATPase activity, host range/helper function, binding to p53, binding to the retinoblastoma susceptibility protein, or nuclear localization had little or no effect on transactivation. These results suggest that N-terminal portion of T antigen possesses an activation activity. The data are consistent with the idea that the overall conformation of T antigen is important for transactivation and that mutations in other regions that reduce or eliminate transactivation do so by altering the conformation or orientation of the N-terminal region so that its ability to interact with various targets is diminished or abolished.     

Thermally inactivated simian virus 40 tsA58 mutant T antigen cannot initiate viral DNA replication in vitro.

The mutation in the temperature-sensitive tsA58 mutant T antigen (Ala-438----Val) lies within the presumptive ATP-binding fold. We have constructed a recombinant baculovirus that expresses large quantities of the tsA58 T antigen in infected insect cells. The mutant T antigen mediated simian virus 40 origin-containing DNA (ori-DNA) synthesis in vitro to nearly the same extent as similar quantities of wild-type T antigen at 33 degrees C. However, if wild-type and tsA58 T antigens were heated at 41 degrees C in replication extracts prior to addition of template DNA, the tsA58 T antigen but not the wild type was completely inactivated. The mutant protein displayed greater thermosensitivity for many of the DNA replication activities of T antigen than did the wild-type protein. Some of the replication functions of tsA58 T antigen were differentially affected depending on the presence or absence of ATP during the preheating period. When tsA58 T antigen was preheated in the presence of ATP at 41 degrees C for a time sufficient to completely inactivate its ability to replicate ori-DNA in vitro, it displayed substantial ATPase and normal DNA helicase activities. Conversely, when preheated in the absence of nucleotide, it completely lost both ATPase and helicase activities. Preheating tsA58 T antigen, even in the presence of ATP, led to drastic reductions in its ability to bind to and unwind DNA containing the replication origin. The mutant T antigen also displayed thermosensitivity for binding to and unwinding nonspecific double-stranded DNA in the presence of ATP. Our results suggest that the interactions of T antigen with ATP that are involved in T-antigen DNA binding and DNA helicase activities are different. Moreover, we conclude, consistent with its phenotype in vivo, that the tsA58 T antigen is defective in the initiation but not in the putative elongation functions of T antigen in vitro.     

Initiation of simian virus 40 DNA replication in vitro.

Exogenously added simian virus 40 (SV40) DNA can be replicated semiconservatively in vitro by a mixture of a soluble extract of HeLa cell nuclei and the cytoplasm from SV40-infected CosI cells. When cloned DNA was used as a template, the clone containing the SV40 origin of DNA replication was active, but a clone lacking the SV40 origin was inactive. The major products of the in vitro reaction were form I and form II SV40 DNAs and a small amount of form III. DNA synthesis in extracts began at or near the in vivo origin of SV40 DNA synthesis and proceeded bidirectionally. The reaction was inhibited by the addition of anti-large T hamster serum, aphidicolin, or RNase but not by ddNTP. Furthermore, this system was partially reconstituted between HeLa nuclear extract and the semipurified SV40 T antigen instead of the CosI cytoplasm. It is clear from these two systems that the proteins containing SV40 T antigen change the nonspecific repair reaction performed by HeLa nuclear extract alone to the specific semiconservative DNA replication reaction. These results show that these in vitro systems closely resemble SV40 DNA replication in vivo and provide an assay that should be useful for the purification and subsequent characterization of viral and cellular proteins involved in DNA replication.     

Altered phosphorylation of free and bound forms of monkey p53 and simian virus 40 large T antigen during lytic infection.

We have identified the phosphorylation sites in monkey p53 as well as specific changes in the phosphorylation state of free and complexed forms of simian virus 40 (SV40) large T antigen (T) and monkey p53 isolate from SV40 lytically infected CV1 cells. Phosphopeptide analyses of free T and p53 (To and p53o) and complexed T and p53 (T+ and p53+) fractions indicated several quantitative increases in the specific phosphorylation of complexed forms of both proteins. The N terminus of monkey p53+ is phosphorylated at Ser-9, Ser-15, Ser-20, either Ser-33 or Ser-37, and at least one of Ser-90 to Ser-99. The C-terminal sites are Ser-315 and Ser-392. On comparing p53+ with p53o, we found that labeling of the two N-terminal phosphotryptic peptides encompassing residues 1 to 20 and 33 to 101 was increased fivefold and that Ser-315 was sevenfold more labeled than was Ser-392. When T+ was compared with To, the N-terminal peptide containing phosphorylation sites Ser-106 through Thr-124 was twofold more labeled, the peptide containing Ser-657 through Ser-679 was sixfold more labeled and contained up to four phosphorylated serine residues, and Ser-639 and Thr-701 appeared unchanged. Overall, T+ molecules appeared to contain 3.5 mol more of labeled phosphate than did To, with the N-terminal peptide appearing fully phosphorylated. The phosphopeptide patterns obtained for lytic T+ and To fractions were nearly identical to those found for wild-type SV40 T (stably complexed with mouse p53) and mutant 5080 T (defective for p53 binding) expressed in transformed C3H10T1/2 cells (L. Tack, C. Cartwright, J. Wright, A. Srinivasan, W. Eckhart, K. Peden, and J. Pipas, J. Virol. 63:3362-3367, 1989). These results indicate that increases in specific phosphorylation sites in both T+ and p53+ correlate with the association of T with p53. The enhanced phosphorylation state may be a consequence of complex formation between T and p53 or reflect an increased affinity of p53 for highly phosphorylated forms of T.     

The p53 complex from monkey cells modulates the biochemical activities of simian virus 40 large T antigen.

We have compared the ATPase, DNA-binding, and helicase activities of free simian virus 40 (SV40) large T antigen (To) and T antigen complexed with cellular p53 (T+p53). Each activity is essential for productive viral infection. The T+p53 and To fractions were prepared by sequential immunosorption of infected monkey cells with monoclonal antibodies specific for p53 and T antigen. The immune-complexed T fractions were then assayed in parallel. For ATP hydrolysis, the Vmax for T+p53 was 143 nmol of ADP per min per mg of protein, or 18-fold greater than for To. ATP had no effect on the stability of the T+p53 complex. The T+p53 complex was significantly more active than To in hydrolyzing dATP, dGTP, GTP, and UTP. Of the nucleotide substrates tested, the greatest relative increase (T+p53/To) was in hydrolyzing dGTP and GTP. In DNase footprinting assays performed under replication conditions, the T+p53 complex protected regions I, II, and III of origin DNA while equivalent amounts of To protected only regions I and II. Region III is known to contribute to the efficiency of DNA replication and contains the SP1-binding sites of the early viral promoter. The T+p53 fraction was also a more efficient helicase than To, especially with a GC-rich primer and template. Thus, the T+p53 complex has enhanced ATPase, GTPase, DNA-binding, and helicase activities. These findings imply that complex formation between cellular monkey p53 and SV40 T antigen modulates a number of essential activities of T in SV40 productive infection.     

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.     

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.     

Simian virus 40 small-t antigen stimulates viral DNA replication in permissive monkey cells.

The simian virus 40 (SV40) large-T antigen is essential for SV40 DNA replication and for late viral gene expression, but the role of the SV40 small-t antigen in these processes is still unclear. We have previously demonstrated that small t inhibits SV40 DNA replication in vitro. In this study, we investigated the effect of small t on SV40 replication in cultured cells. CV1 monkey cell infection experiments indicated that mutant viruses that lack small t replicate less efficiently than the wild-type virus. We next microinjected CV1 cells with SV40 DNA with and without purified small-t protein and analyzed viral DNA replication efficiency by Southern blotting. Replication of either wild-type SV40 or small-t deletion mutant DNA was increased three- to fivefold in cells coinjected with purified small t. Thus, in contrast to our in vitro observation, small t stimulated viral DNA replication in vivo. This result suggests that small t has cellular effects that are not detectable in a reconstituted in vitro replication system. We also found that small t stimulated progression of permissive monkey cells--but not of nonpermissive rodent cells--from G0-G1 to the S phase of the cell cycle, possibly leading to an optimal intracellular environment for viral replication.     

Murine cell complementation of a cold-sensitive defect for simian virus 40 replication in simian cells.

Mouse 3T3 fibroblasts were found to complement, in simian cell variants semipermissive to simian virus 40, a cold-sensitive defect of an early function, but not a nonconditional defect of viral uncoating. The variant simian cells could rescue simian virus 40 from 3T3 transformants, and this capacity was not temperature dependent.     

An N-terminal deletion mutant of simian virus 40 (SV40) large T antigen oligomerizes incorrectly on SV40 DNA but retains the ability to bind to DNA polymerase alpha and replicate SV40 DNA in vitro.

A peptide encompassing the N-terminal 82 amino acids of simian virus 40 (SV40) large T antigen was previously shown to bind to the large subunit of DNA polymerase alpha-primase (I. Dornreiter, A. Höss, A. K. Arthur, and E. Fanning, EMBO J. 9:3329-3336, 1990). We report here that a mutant T antigen, T83-708, lacking residues 2 to 82 retained the ability to bind to DNA polymerase alpha-primase, implying that it carries a second binding site for DNA polymerase alpha-primase. The mutant protein also retained ATPase, helicase, and SV40 origin DNA-binding activity. However, its SV40 DNA replication activity in vitro was reduced compared with that of wild-type protein. The reduction in replication activity was accompanied by a lower DNA-binding affinity to SV40 origin sequences and aberrant oligomerization on viral origin DNA. Thus, the first 82 residues of SV40 T antigen are not strictly required for its interaction with DNA polymerase alpha-primase or for DNA replication function but may play a role in correct hexamer assembly and efficient DNA binding at the origin.     

Salt-resistant association of simian virus 40 T antigen with simian virus 40 DNA in nucleoprotein complexes.

Treatment of nucleoprotein complexes (NPCs) from simian virus 40 (SV40)-infected TC7 cells with NaCl (1 or 2 M) or guanidine-hydrochloride (1 or 2 M) resulted in a significant fraction of T antigen still associated with SV40 (I) DNA. Immunoprecipitation of the salt-treated NPCs with SV40 anti-T serum indicated that T antigen is preferentially associated with SV40 (I) DNA rather than with SV40 (II) DNA. Treatment of the NPCs with 4 M guanidine-hydrochloride, however, resulted in a substantial decrease in the amount of SV40 (I) and (II) DNA associated with T antigen. As the temperature was increased to 37 degrees C during incubation of NPCs with NaCl or guanidine-hydrochloride, there was a decrease in the amount of SV40 (I) and (II) DNA immunoprecipitated with SV40 anti-T serum. In the absence of salt, temperature had no effect on the association of T antigen with the SV40 DNA in the NPCs. Treatment of NPCs from SV40 wildtype or tsA58-infected cells grown at the permissive temperature with 1 or 2 M NaCl indicated that tsA T antigen has the same sensitivities as wild-type T antigen to high salt treatment when bound to DNA in NPCs. Characterization of the proteins associated with SV40 (I) DNA after high salt treatment revealed that, in addition to T antigen, a certain amount of viral capsid proteins VP1 and VP3 remained associated with the DNA. Complexes containing SV40 (I) DNA had a sedimentation value of 53S after 1 M NaCl treatment and 43S after 2 M NaCl treatment.     

Mechanisms of interference with simian virus 40 (SV40) DNA replication by trans-dominant mutants of SV40 large T antigen.

Mutations at multiple sites within the simian virus 40 (SV40) early region yield large T antigens which interfere trans dominantly with the replicative activities of wild-type T antigen. A series of experiments were conducted to study possible mechanisms of interference with SV40 DNA replication caused by these mutant T antigens. First, the levels of wild-type T antigen expression in cells cotransfected with wild-type and mutant SV40 DNAs were examined; approximately equal levels of wild-type T antigen were seen, regardless of whether the cotransfected mutant was trans dominant or not. Second, double mutants that contained the mutation of inA2827, a strong trans-dominant mutation with a 12-bp linker inserted at the position encoding amino acid 520, and various mutations in other parts of the large-T-antigen coding region were constructed. The trans-dominant interference of inA2827 was not affected by second mutations within the p105Rb binding site or the amino or carboxy terminus of large T antigen. Mutation of the nuclear localization signal partially reduced the trans dominance of inA2827. The large T antigen of mutant inA2815 contains an insertion of 4 amino acids at position 168 of large T; this T antigen fails to bind SV40 DNA but is not trans dominant for DNA replication. The double mutant containing the mutations of both inA2815 and in A2827 was not trans dominant. The large T antigen of dlA2433 lacks amino acids 587 to 589, was unstable, and failed to bind p53. Combining the dlA2433 mutation with the inA2827 mutation also reversed the trans dominance completely, but the effect of the dlA2433 mutation on trans dominance can be explained by the instability of this double mutant protein. In addition, we examined several mutants with conservative point mutations in the DNA binding domain and found that most of them were not trans dominant. The implications of the results of these experiments on possible mechanisms of trans dominance are discussed.     

Primer-DNA formation during simian virus 40 DNA replication in vitro.

Studies of simian virus 40 (SV40) DNA replication in vitro have identified a small (approximately 30-nucleotide) RNA-DNA hybrid species termed primer-DNA. Initial experiments indicated that T antigen and the polymerase alpha-primase complex are required to form primer-DNA. Proliferating cell nuclear antigen, and presumably proliferating cell nuclear antigen-dependent polymerases, is not needed to form this species. Herein, we present an investigation of the stages at which primer-DNA functions during SV40 DNA replication in vitro. Hybridization studies indicate that primer-DNA is initially formed in the origin region and is subsequently synthesized in regions distal to the origin. At all time points, primer-DNA is synthesized from templates for lagging-strand DNA replication. These studies indicate that primer-DNA functions during both initiation and elongation stages of SV40 DNA synthesis. Results of additional experiments suggesting a precursor-product relationship between formation of primer-DNA and Okazaki fragments are presented.     

Removal of serine phosphates from simian virus 40 large T antigen increases its ability to stimulate DNA replication in vitro but has no effect on ATPase and DNA binding.

The effect of phosphorylation on the ability of simian virus 40 large T antigen to stimulate DNA synthesis in vitro was tested. Treatment of affinity-purified large T antigen with calf intestinal alkaline phosphatase resulted in the removal of 70 to 80% of the phosphate residues. Only serine-bound phosphate residues were affected. Phosphatase-treated large T antigen stimulated in vitro DNA synthesis fourfold over the untreated control. The stimulation was strongest at early times of DNA replication. At later times, DNA replication proceeded at equal rates with dephosphorylated and untreated large T antigen. The ATPase activity of large T antigen was not affected by phosphatase treatment. The origin-binding activity of large T antigen was tested over a wide range of large T antigen to DNA ratios, including DNA excess, and in the presence and absence of carrier DNA. Under no condition was an effect of dephosphorylation of large T antigen on its DNA-binding activity observed. These findings might indicate that phosphorylation at serine residues modulates the interaction of large T antigen with cellular factors. During DNA synthesis large T antigen was substantially rephosphorylated by kinases in the HeLa cell extract. As shown by two-dimensional peptide mapping, this phosphorylation occurred at all known in vivo sites. No phosphatase and protease activities were detectable in the HeLa cell extract.     

The binding of topoisomerase I to T antigen enhances the synthesis of RNA-DNA primers during simian virus 40 DNA replication

Topoisomerase I (topo I) is required for the proper initiation of simian virus 40 (SV40) DNA replication. This enzyme binds to SV40 large T antigen at two places, close to the N-terminal end and near the C-terminal end of the helicase domain. We have recently demonstrated that the binding of topo I to the C-terminal site is necessary for the stimulation of DNA synthesis by topo I and for the formation of normal amounts of completed daughter molecules. In this study, we investigated the mechanism by which this stimulation occurs. Contrary to our expectation that the binding of topo I to this region of T antigen provides the proper unwound DNA substrate for initiation to occur, we demonstrate that binding of topo I stimulates polymerase alpha/primase (pol/prim) to synthesize larger amounts of primers consisting of short RNA and about 30 nucleotides of DNA. Topo I binding also stimulates the production of large molecular weight DNA by pol/prim. Mutant T antigens that fail to bind topo I normally do not participate in the synthesis of expected amounts of primers or large molecular weight DNAs indicating that the association of topo I with the C-terminal binding site on T antigen is required for these activities. It is also shown that topo I has the ability to bind to human RPA directly, suggesting that the stimulation of pol/prim activity may be mediated in part through RPA in the DNA synthesis initiation complex.