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.     

Simian virus 40 DNA replication is dependent on an interaction between topoisomerase I and the C-terminal end of T antigen

Topoisomerase I (topo I) is needed for efficient initiation of simian virus 40 (SV40) DNA replication and for the formation of completed DNA molecules. Two distinct binding sites for topo I have been previously mapped to the N-terminal (residues 83 to 160) and C-terminal (residues 602 to 708) regions of T antigen. By mutational analysis, we identified a cluster of six residues on the surface of the helicase domain at the C-terminal binding site that are necessary for efficient binding to topo I in enzyme-linked immunosorbent assay and far-Western blot assays. Mutant T antigens with single substitutions of these residues were unable to participate normally in SV40 DNA replication. Some mutants were completely defective in supporting DNA replication, and replication was not enhanced in the presence of added topo I. The same mutants were the ones that were severely compromised in binding topo I. Other mutants demonstrated intermediate levels of activity in the DNA replication assay and were correspondingly only partially defective in binding topo I. Mutations of nearby residues outside this cluster had no effect on DNA replication or on the ability to bind topo I. These results strongly indicate that the association of topo I with these six residues in T antigen is essential for DNA replication. These residues are located on the back edges of the T-antigen double hexamer. We propose that topo I binds to one site on each hexamer to permit the initiation of SV40 DNA 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.     

Assembly of the replication initiation complex on SV40 origin DNA

The assembly of the complex that forms over the simian virus 40 origin to initiate DNA replication is not well understood. This complex is composed of the virus-coded T antigen and three cellular proteins, replication protein A (RPA), DNA polymerase α/primase (pol/prim) and topoisomerase I (topo I) in association with the origin. The order in which these various proteins bind to the DNA was investigated by performing binding assays using biotinylated origin DNA. We demonstrate that in the presence of all four proteins, pol/prim was essential to stabilize the initiation complex from the disruptive effects of topo I. At the optimal concentration of pol/prim, topo I and RPA bound efficiently to the complex, although pol/prim itself was not detected in significant amounts. At higher concentrations less topo I was recruited, suggesting that DNA polymerase is an important modulator of the binding of topo I. Topo I, in turn, appeared to be involved in recruiting RPA. RPA, in contrast, seemed to have little or no effect on the recruitment of the other proteins to the origin. These and other data suggested that pol/prim is the first cellular protein to interact with the double-hexameric T antigen bound to the origin. This is likely followed by topo I and then RPA, or perhaps by a complex of topo I and RPA. Stoichiometric analysis of the topo I and T antigen present in the complex suggested that two molecules of topo I are recruited per double hexamer. Finally, we demonstrate that DNA has a role in recruiting topo I to the origin.     

The cap region of topoisomerase I binds to sites near both ends of simian virus 40 T antigen

Two independent binding sites on simian virus 40 (SV40) T antigen for topoisomerase I (topo I) were identified. One was mapped to the N-terminal domain (residues 83 to 160) by a combination of enzyme-linked immunosorbent assays (ELISAs) and glutathione S-transferase (GST) pull-down assays performed with various T antigen deletion mutants. The second was mapped to the C-terminal domain (residues 602 to 708). The region in human topo I that binds to both sites in T antigen was identified by ELISAs, GST pull-down assays, and double-hexamer binding assays with topo I deletion mutants. This region corresponds to a distinct domain on topo I known as the cap region that maps from residues 175 to 433. By combining these data with information about the structure of T-antigen double hexamers associated with origin DNA, we propose that the cap region of topo I associates specifically with both ends of the double hexamer bound to the SV40 origin to initiate DNA replication.     

Initiation of simian virus 40 DNA replication requires the interaction of a specific domain of human DNA polymerase alpha with large T antigen.

Initiation of cell-free simian virus 40 (SV40) DNA replication requires the interaction of DNA polymerase alpha/primase with a preinitiation complex containing the viral T antigen and cellular proteins, replication protein A, and topoisomerase I or II. To further understand the molecular mechanisms of the transition from preinitiation to initiation, the intermolecular interaction between human DNA polymerase alpha and T antigen was investigated. We have demonstrated that the human DNA polymerase alpha catalytic polypeptide is able to associate with SV40 large T antigen directly under physiological conditions. A physical association between these two proteins was detected by coimmunoprecipitation with monoclonal antibodies from insect cells coinfected with recombinant baculoviruses. A domain of human polymerase alpha physically interacting with T antigen was identified within the amino-terminal region from residues 195 to 313. This domain of human polymerase alpha was able to form a nonproductive complex with T antigen, causing inhibition of the SV40 DNA replication in vitro. Kinetics of the inhibition indicated that this polymerase domain can inhibit viral replication only during the preinitiation stage. Extra molecules of T antigen could partially overcome the inhibition only prior to initiation complex formation. The data support the conclusion that initiation of SV40 DNA replication requires the physical interaction of T antigen in the preinitiation complex with the amino-terminal domain of human polymerase alpha from amino acid residues 195 to 313.     

The mouse DNA polymerase alpha-primase subunit p48 mediates species-specific replication of polyomavirus DNA in vitro.

Mouse cell extracts support vigorous replication of polyomavirus (Py) DNA in vitro, while human cell extracts do not. However, the addition of purified mouse DNA polymerase alpha-primase to human cell extracts renders them permissive for Py DNA replication, suggesting that mouse polymerase alpha-primase determines the species specificity of Py DNA replication. We set out to identify the subunit of mouse polymerase alpha-primase that mediates this species specificity. To this end, we cloned and expressed cDNAs encoding all four subunits of mouse and human polymerase alpha-primase. Purified recombinant mouse polymerase alpha-primase and a hybrid DNA polymerase alpha-primase complex composed of human subunits p180 and p68 and mouse subunits p58 and p48 supported Py DNA replication in human cell extracts depleted of polymerase alpha-primase, suggesting that the primase heterodimer or one of its subunits controls host specificity. To determine whether both mouse primase subunits were required, recombinant hybrid polymerase alpha-primases containing only one mouse primase subunit, p48 or p58, together with three human subunits, were assayed for Py replication activity. Only the hybrid containing mouse p48 efficiently replicated Py DNA in depleted human cell extracts. Moreover, in a purified initiation assay containing Py T antigen, replication protein A (RP-A) and topoisomerase I, only the hybrid polymerase alpha-primase containing the mouse p48 subunit initiated primer synthesis on Py origin DNA. Together, these results indicate that the p48 subunit is primarily responsible for the species specificity of Py DNA replication in vitro. Specific physical association of Py T antigen with purified recombinant DNA polymerase alpha-primase, mouse DNA primase heterodimer, and mouse p48 suggested that direct interactions between Py T antigen and primase could play a role in species-specific initiation of Py replication.     

Simian virus 40 DNA replication in vitro: specificity of initiation and evidence for bidirectional replication.

We recently described a soluble cell-free system derived from monkey cells that is capable of replicating exogenous plasmid DNA molecules containing the simian virus 40 (SV40) origin of replication (J.J. Li, and T.J. Kelly, Proc. Natl. Acad. Sci. U.S.A. 81:6973-6977, 1984). Replication in the system is completely dependent upon the addition of the SV40 large T antigen. In this report we describe additional properties of the in vitro replication reaction. Extracts prepared from cells of several nonsimian species were tested for the ability to support origin-dependent replication in the presence of T antigen. The activities of extracts derived from human cell lines HeLa and 293 were approximately the same as those of monkey cell extracts. Chinese hamster ovary cell extracts also supported SV40 DNA replication in vitro, but the extent of replication was approximately 1% of that observed with human or monkey cell extracts. No replication activity was detectable in extracts derived from BALB/3T3 mouse cells. The ability of these extracts to support replication in vitro closely parallels the ability of the same cells to support replication in vivo. We also examined the ability of various DNA molecules containing sequences homologous to the SV40 origin to serve as templates in the cell-free system. Plasmids containing the origins of human papovaviruses BKV and JCV replicated with an efficiency 10 to 20% of that of plasmids containing the SV40 origin. Plasmids containing Alu repeat sequences (BLUR8) did not support detectable DNA replication in vitro. Circular DNA molecules were found to be the best templates for DNA replication in the cell-free system; however, linear DNA molecules containing the SV40 origin also replicated to a significant extent (10 to 20% of circular molecules). Finally, electron microscopy of replication intermediates demonstrated that the initiation of DNA synthesis in vivo takes place at a unique site corresponding to the in vivo origin and that replication is bidirectional. These findings provide further evidence that replication in the cell-free system faithfully mimics SV40 DNA replication in vivo.     

DNA ligase I and proliferating cell nuclear antigen form a functional complex

DNA ligase I is responsible for joining Okazaki fragments during DNA replication. An additional proposed role for DNA ligase I is sealing nicks generated during excision repair. Previous studies have shown that there is a physical interaction between DNA ligase I and proliferating cell nuclear antigen (PCNA), another important component of DNA replication and repair. The results shown here indicate that human PCNA enhances the reaction rate of human DNA ligase I up to 5-fold. The stimulation is specific to DNA ligase I because T4 DNA ligase is not affected. Electrophoretic mobility shift assays indicate that PCNA improves the binding of DNA ligase I to the ligation site. Increasing the DNA ligase I concentration leads to a reduction in PCNA stimulation, consistent with PCNA-directed improvement of DNA ligase I binding to its DNA substrate. Two experiments show that PCNA is required to encircle duplex DNA to enhance DNA ligase I activity. Biotin-streptavidin conjugations at the ends of a linear substrate inhibit PCNA stimulation. PCNA cannot enhance ligation on a circular substrate without the addition of replication factor C, which is the protein responsible for loading PCNA onto duplex DNA. These results show that PCNA is responsible for the stable association of DNA ligase I to nicked duplex DNA.     

Identification of cellular proteins required for simian virus 40 DNA replication

Study of the proteins involved in DNA replication of a model system such as SV40 is a first step in understanding eukaryotic chromosomal replication. Using a cell-free system that is capable of replicating plasmid DNA molecules containing the SV40 origin of replication, we conducted a series of systematic fractionation-reconstitution experiments for the purpose of identifying and characterizing the cellular proteins involved in SV40 DNA replication. In addition to the one viral-encoded replication protein, T antigen, we have identified and begun to characterize at least six cellular components from a HeLa cytoplasmic extract that are absolutely required for SV40 DNA replication in vitro. These include: (i) two partially purified fractions, CF IC and CF IIA, and (ii) four proteins that have been purified to near homogeneity, replication protein-A, proliferating cell nuclear antigen, DNA polymerase alpha-primase complex, and topoisomerase (I and II). Replication protein-A is a multi-subunit protein that has single-stranded DNA binding activity and is required for a T antigen-dependent, origin-dependent unwinding reaction which may be an important early step in initiation of replication. Fraction CF IC can stimulate this unwinding reaction, suggesting that it also may function during initiation. Proliferating cell nuclear antigen, DNA polymerase alpha-primase, and CF IIA all appear to be involved in elongation of nascent chains.     

Replication and supercoiling of simian virus 40 DNA in cell extracts from human cells.

Soluble extracts prepared from the nucleus and cytoplasm of human 293 cells are capable of efficient replication and supercoiling of added DNA templates that contain the origin of simian virus 40 replication. Extracts prepared from human HeLa cells are less active than similarly prepared extracts from 293 cells for initiation and elongation of nascent DNA strands. DNA synthesis is dependent on addition of purified simian virus 40 tumor (T) antigen, which is isolated by immunoaffinity chromatography of extracts from cells infected with an adenovirus modified to produce large quantities of this protein. In the presence of T antigen and the cytoplasmic extract, replication initiates at the origin and continues bidirectionally. Initiation is completely dependent on functional origin sequences; a plasmid DNA containing an origin mutation known to affect DNA replication in vivo fails to replicate in vitro. Multiple rounds of DNA synthesis occur, as shown by the appearance of heavy-heavy, bromodeoxyuridine-labeled DNA products. The products of this reaction are resolved, but are relaxed, covalently closed DNA circles. Addition of a nuclear extract during DNA synthesis promotes the negative supercoiling of the replicated DNA molecules.     

Knotting dynamics during DNA replication

The topology of plasmid DNA changes continuously as replication progresses. But the dynamics of the process remains to be fully understood. Knotted bubbles form when topo IV knots the daughter duplexes behind the fork in response to their degree of intertwining. Here, we show that knotted bubbles can form during unimpaired DNA replication, but they become more evident in partially replicated intermediates containing a stalled fork. To learn more about the dynamics of knot formation as replication advances, we used two-dimensional agarose gel electrophoresis to identify knotted bubbles in partially replicated molecules in which the replication fork stalled at different stages of the process. The number and complexity of knotted bubbles rose as a function of bubble size, suggesting that knotting is affected by both precatenane density and bubble size.     

Targeting of PCNA to sites of DNA replication in the mammalian cell nucleus

We have examined the targeting of proliferating cell nuclear antigen (PCNA), an integral component of the mammalian replicative enzyme DNA polymerase delta, with sites of DNA replication by using confocal microscopy and computer image analysis. Labeling (5 min pulse) of DNA replication sites in normal human diploid fibroblast cells (NHF1) with BrdU was followed by immunostaining with PCNA antibodies. A striking degree of colocalization was seen between PCNA and the characteristic patterns of DNA replication sites of early, middle and late S-phase (Nakayasu and Berezney [1989] J. Cell. Biol. 108:1-11). These observations were confirmed by quantitative computer image analysis which revealed that approximately 90% of the PCNA-stained area overlapped with DNA replication sites in early S-phase. Pulse-chase experiments, involving in vivo labeling for replication followed by PCNA staining at later time points, suggested that PCNA disassembles from previously replicated sites and targets to newly active sites of DNA replication. To further study this phenomenon in living cells, stable GFP-PCNA transfectants under the control of a tetracycline-inducible promoter were created in mouse 3T6 cells. Like the endogenous PCNA, GFP-PCNA targeted to sites of replication (approximately 80% colocalization) and demonstrated similar dynamic changes following pulse-chase experiments in fixed cells. Studies of living cells revealed progressive changes in the GFP-PCNA distribution that mimic the replication patterns observed in fixed cells. We conclude that GFP-PCNA targets to DNA replication sites in living cells and is an effective marker for tracking the spatio-temporal dynamics of DNA replication as cells transverse the S-phase.     

E1A specifically enhances sensitivity to topoisomerase IIalpha targeting anticancer drug by up-regulating the promoter activity

DNA topoisomerases I and II (topo I and II) are nuclear enzymes involved in cellular replication and are targets for several anticancer drugs. We showed previously that E1A gene transfer enhanced the sensitivity of Ewing's sarcoma cells to the topo IIalpha targeting agents etoposide and Adriamycin in vitro and in vivo. To determine whether this effect was specific for topo IIalpha, we investigated the effect of E1A gene transfer on cell sensitivity to agents that target topo I and IIbeta. Transfecting TC71 human Ewing's sarcoma cells with an adenoviral vector containing the E1A gene enhanced their sensitivity to the topo IIalpha targeting agents etoposide (16-fold) and Adriamycin (8-fold). By contrast, E1A gene transfer did not affect cellular sensitivity to either amsacrine or camptothecin. Western blot analysis indicated that topo IIalpha protein levels increased 3.1-fold after E1A gene transfer, but topo I and IIbeta protein levels did not change. A plasmid containing topo IIalpha gene promoter with luciferase reporter gene was constructed to determine the effects of E1A gene transfer on the activity of the topo IIalpha promoter. E1A increased the activity of the topo IIalpha gene promoter by 3.5-fold relative to that of cells transfected with Ad-beta-gal. These results suggest that elevated topo IIalpha protein levels and enhanced sensitivity to topo IIalpha targeting agents were secondary to a direct effect of E1A on the topo IIalpha promoter. Combining E1A gene therapy with topo IIalpha targeting anticancer drugs may therefore have therapeutic benefit by increasing tumor cell sensitivity.     

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.     

Unwinding of origin-specific structures by human replication protein A occurs in a two-step process.

The simian virus 40 (SV40) large tumor antigen(T antigen) has been shown to induce the melting of 8 bp within the SV40 origin of replication. We found previously that a 'pseudo-origin' DNA molecule (PO-8) containing a central 8 nt single-stranded DNA (ssDNA) bubble was efficiently bound and denatured by human replication protein A (hRPA). To understand the mechanism by which hRPA denatures these pseudo-origin molecules, as well as the role that hRPA plays during the initiation of SV40 DNA replication, we characterized the key parameters for the pseudo-origin binding and denaturation reactions. The dissociation constant of hRPA binding to PO-8 was observed to be 7.7 x 10(-7) M, compared to 9.0 x 10(-8) M for binding to an identical length ssDNA under the same reaction conditions. The binding and denaturation of PO-8 occurred with different kinetics with the rate of binding determined to be approximately 4-fold greater than the rate of denaturation. Although hRPA binding to PO-8 was relatively temperature independent, an increase in incubation temperature from 4 to 37 degreesC stimulated denaturation nearly 4-fold. At 37 degreesC, denaturation occurred on approximately 1/3 of those substrate molecules bound by hRPA, showing that hRPA can bind the pseudo-origin substrate without causing its complete denaturation. Tests of other single-stranded DNA-binding proteins (SSBs) over a range of SSB concentrations revealed that the ability of the SSBs to bind the pseudo-origin substrate, rather than denature the substrate, correlated best with the known ability of these SSBs to support the T antigen-dependent SV40 origin-unwinding activity. Our data indicate that hRPA first binds the DNA substrate using a combination of contacts with the ssDNA bubble and duplex DNA flanks and then, on only a fraction of the bound substrate molecules, denatures the DNA substrate.     

The two chromosomes of Vibrio cholerae are initiated at different time points in the cell cycle

The bacterium Vibrio cholerae, the cause of the diarrhoeal disease cholera, has its genome divided between two chromosomes, a feature uncommon for bacteria. The two chromosomes are of different sizes and different initiator molecules control their replication independently. Using novel methods for analysing flow cytometry data and marker frequency analysis, we show that the small chromosome II is replicated late in the C period of the cell cycle, where most of chromosome I has been replicated. Owing to the delay in initiation of chromosome II, the two chromosomes terminate replication at approximately the same time and the average number of replication origins per cell is higher for chromosome I than for chromosome II. Analysis of cell-cycle parameters shows that chromosome replication and segregation is exceptionally fast in V. cholerae. The divided genome and delayed replication of chromosome II may reduce the metabolic burden and complexity of chromosome replication by postponing DNA synthesis to the last part of the cell cycle and reducing the need for overlapping replication cycles during rapid proliferation.     

Chromatin assembly during SV40 DNA replication in vitro

A cytosol extract from human 293 cells supports efficient replication of SV40 origin-containing plasmid DNA in the presence of the SV40 T antigen. Addition of a nuclear extract from the same cells promotes negative supercoiling of the replicated DNA but not the bulk of the unreplicated DNA. The level of superhelicity is affected by the concentrations of T antigen and nuclear extract factors and by the time of addition of the nuclear extract. The replicated DNA in isolated DNA-protein complexes resists relaxation by purified HeLa cell topoisomerase I. Micrococcal nuclease digestion, sucrose gradient sedimentation, and electron microscopy demonstrate that the negative supercoils result from assembly of the replicating DNA into a chromatin structure. These results suggest that, during DNA replication, the core histones can be assembled on both sides of the replication fork by an active, replication-linked mechanism that does not require a template of preexisting nucleosomes.