Simian Virus 40 DNA Replication in Isolated Replicating Viral Chromosomes

Three subnuclear systems capable of continuing many aspects of simian virus 40 (SV40) DNA replication were characterized in an effort to define the minimum requirements for "normal" DNA replication in vitro. Nuclear extracts, prepared by incubating nuclei isolated from SV40-infected CV-1 cells in a hypotonic buffer to release both SV40 replicating and mature chromosomes, were either centrifuged to separate the total SV40 nucleoprotein complexes from the soluble nucleosol or fractionated on sucrose gradients to provide purified SV40 replicating chromosomes. With nuclear extracts, CV-1 cell cytosol stimulated total DNA synthesis, elongation of nascent DNA chains, maturation and joining of "Okazaki pieces," and the conversion of replicating viral DNA into covalently closed, superhelical DNA. Nucleoprotein complexes responded similarly, but frequently the response was reduced by 10 to 30%. In contrast, isolated replicating chromosomes in the presence of cytosol appeared only to complete and join Okazaki pieces already present on the template; without cytosol, Okazaki pieces incorporated alpha-(32)P-labeled deoxynucleoside triphosphates but failed to join. Consequently, replicating chromosomes failed to extensively continue nascent DNA chain growth, and the conversion of viral replicating DNA into mature DNA was seven to eight times less than that observed in nuclear extracts. Addition of neither cytosol nor nucleosol corrected this problem. In the presence of cytosol, nonspecific endonuclease activity was not a problem in any of the three in vitro systems. Extensive purification of replicating chromosomes was limited by three as yet irreversible phenomena. First, replicating chromosomes isolated in a low-ionic-strength medium had a limited capability to continue DNA synthesis. Second, diluting either nuclear extracts or replicating chromosomes before incubation in vitro stimulated total DNA synthesis but was accompanied by the simultaneous appearance of small-molecular-weight nascent DNA not associated with intact viral DNA templates and a decrease in the synthesis of covalently closed viral DNA. Although this second phenomenon appeared similar to the first, template concentration alone could not account for the failure of purified replicating chromosomes to yield covalently closed DNA. Finally, preparation of nucleoprotein complexes in increasing concentrations of NaCl progressively decreased their ability to continue DNA replication. Exposure to 0.3 M NaCl removed one or more factors required for DNA synthesis which could be replaced by addition of cytosol. However, higher NaCl concentrations yielded nucleoprotein complexes that had relatively no endogenous DNA synthesis activity and that no longer responded to cytosol. These data demonstrate that continuation of endogenous DNA replication in vitro requires both the soluble cytosol fraction and a complex nucleoprotein template whose ability to continue DNA synthesis depends on its concentration and ionic environment during its preparation.     

The relationship of SV40 replicating chromosomes to two forms of the non-replicating SV40.

SV40 replicating chromosomes were extracted from infected cells using a detergent free extraction method. This procedure also extracts 2 forms of the non-replicating chromosome, one of which corresponds to the well characterized 50-55S SV40 minichromosome. The other is a more compact structure which has a sedimentation coefficient of 80-85S. The replicating chromosomes sediment between the 2 conformations of the mature chromosome. Electron microscopy of the replicating chromosomes suggests an overall conformation that resembles the 50-55S form of the mature chromosome rather than that of the 80-85S structure. Nucleosomes are present on both sides of the replication forks. When the replicating chromosomes were incubated in an in vitro DNA synthesis assay all regions of the SV40 genome were synthesized and a significant fraction of the replicating chromosomes completed replication. The progeny chromosomes co-sedimented with the 50-55S chromosomes which were present prior to the incubation. The sedimentation coefficients and relative amounts of the two forms of the mature chromosome were unaffected by the incubation.     

Interactions between SV40 T antigen and DNA polymerase alpha

Simian virus 40 large T antigen is the only viral protein required for SV40 DNA synthesis in vivo and in vitro. This complex protein recruits the cellular DNA replication apparatus to the SV40 origin and provides a good model for the initiation of cellular DNA replication. The interaction between SV40 large T antigen (TAg) and DNA polymerase alpha has been shown previously to be inhibited by murine p53, the nuclear protein product of a cellular anti-oncogene. The murine p53 protein will inhibit SV40 replication both in vivo and in vitro. Using monoclonal antibodies to TAg, p53, and polymerase alpha, we developed immunoassays to measure the complexes formed between TAg and polymerase alpha and between TAg and p53. The assays allowed us to detect the TAg-polymerase alpha and TAg-p53 complexes in lytically infected and transformed cells. The amount of TAg complexed to p53 was far lower in infected cells than in transformed cells. We used a large range of monoclonal antibodies to different sites on T antigen and found that antibodies that inhibited the formation of the TAg-polymerase alpha complex also inhibited the formation of the TAg-p53 complex. Finally, we found that the tsA58 and 5080 point mutations in TAg, previously shown to inhibit the binding of TAg to p53, also inhibit its binding to polymerase alpha. Together these results emphasize the specificity and functional importance of the TAg-polymerase alpha complex. The disruption of this interaction by the cellular anti-oncogene p53 provides an interesting model for the normal action of p53 and the effects of its removal on the regulation of cellular DNA synthesis.     

Structure of chromatin at deoxyribonucleic acid replication forks: prenucleosomal deoxyribonucleic acid is rapidly excised from replicating simian virus 40 chromosomes by micrococcal nuclease

Replicating simian virus 40 (SV40) chromosomes were found to be similar to other eukaryotic chromosomes in that the rate and extent of micrococcal nuclease (MNase) digestion were greater with replicating than with nonreplicating mature SV40 chromatin. MNase digestion of replicating SV40 chromosomes, pulse labeled in either intact cells or nuclear extracts, resulted in the rapid release of nascent DNA as essentially bare fragments of duplex DNA (3-7S) that had an average length of 120 base pairs and were degraded during the course of the reaction. In addition, nucleosomal monomers, equivalent in size to those from mature chromosomes, were released. On the other hand, MNase digestion of uniformly labeled mature SV40 chromosomes resulted in the release of only nucleosomal monomers and oligomers. The small nascent DNA fragments released from replicating chromosomes represented prenucleosomal DNA (PN-DNA) from the region of replication forks that encompasses the actual sites of DNA synthesis and includes Okazaki fragments. Predigestion of replicating SV40 chromosomes with both Escherichia coli exonuclease III (3'-5') and bacteriophage T7 gene 6 exonuclease (5'-3') resulted in complete degradation of PN-DNA. This result, together with the observation that isolated PN-DNA annealed equally well to both strands of SV40 restriction fragments, demonstrated that PN-DNA originates from both sides of replication forks. Over 90% of isolated Okazaki fragments annealed only to the retrograde DNA template. The characteristics of isolated PN-DNA were assessed by examining its sensitivity to MNase and single strand specific S1 endonuclease, sedimentation behavior before and after deproteinization, buoyant density in CsCl after formaldehyde treatment, and size on agarose gels. In addition, it was observed that MNase digestion of purified SV40 DNA also resulted in the release of a transient intermediate similar in size to PN-DNA, indicating that a DNA-protein complex is not required to account for the appearance of PN-DNA. These and other data provide a model of replicating chromosomes in which DNA synthesis occurs on a region of replication forks that is free of nucleosomes and is designated as prenucleosomal DNA.     

Simian virus 40 large tumor antigen on replicating viral chromatin: tight binding and localization on the viral genome

Pulse-labeled simian virus 40 (SV40) chromatin as well as uniformly labeled viral chromatin are immunoprecipitable by an SV40-specific tumor antiserum and therefore contain bound tumor antigen (T antigen). Single-stranded calf thymus DNA, immobilized on cellulose, competes effectively for T antigen binding with uniformly labeled nonreplicating, but not with pulse-labeled replicating, chromatin. Furthermore, T antigen dissociates in 0.5 M NaCl from nonreplicating chromatin and from purified SV40 DNA, whereas most T antigen remains associated with replicating chromatin even in the presence of 1.2 to 1.5 M NaCl. We used filtration through DNA-cellulose columns and treatment with high salt to prepare pulse-labeled immunoreactive viral chromatin. The viral DNA was digested before, and in other experiments after, immunoprecipitation with the restriction endonuclease HindIII. We found that SV40 DNA sequences, most probably representing the entire genome, remain in the immunoprecipitate after HindIII digestion, indicating an association of T antigen with origin-distal sections of replicating viral DNA. The results suggest that T antigen in replicating chromatin may be bound to regions close to replicating points. We performed control experiments with in vitro-formed complexes of T antigen and SV40 DNA. When these complexes were immunoprecipitated and HindIII digested we found, in agreement with previous studies, that only the origin containing the HindIII C fragment carried bound T antigen.     

Specific association of simian virus 40 tumor antigen with simian virus 40 chromatin

Simian virus 40 tumor antigen (SV40 T antigen) was bound to both replicating and fully replicated SV40 chromatin extracted with a low-salt buffer from the nuclei of infected cells, and at least a part of the association was tight specific. T antigen cosedimented on sucrose gradients with SV40 chromatin, and T antigen-chromatin complexes could be precipitated from the nuclear extract specifically with anti-T serum. From 10 to 20% of viral DNA labeled to steady state with [3H]thymidine for 12 h late in infection or 40 to 50% of replicating viral DNA pulse-labeled for 5 min was associated with T antigen in such immunoprecipitates. After reaction with antibody, most of the T antigen-chromatin complex was stable to washing with 0.5 M NaCl, but only about 20% of the DNA label remained in the precipitate after washing with 0.5 M NaCl-0.4% Sarkosyl. This tightly bound class of T antigen was associated preferentially with a subfraction of pulse-labeled replicating DNA which comigrated with an SV40 form I marker. A tight binding site for T antigen was identified tentatively by removing the histones with dextran sulfate and heparin from immunoprecipitated chromatin labeled with [32P]phosphate to steady state and then digesting the DNA with restriction endonucleases HinfI and HpaII. The site was within the fragment spanning the origin of replication, 0.641 to 0.725 on the SV40 map.     

Deoxyribonucleic Acid Replication in Simian Virus 40-Infected Cells IV. Two Different Requirements for Protein Synthesis During Simian Virus 40 Deoxyribonucleic Acid Replication

The replication of simian virus 40 (SV40) deoxyribonucleic acid (DNA) was inhibited by 99% 2 hr after the addition of cycloheximide to SV40-infected primary African green monkey kidney cells. The levels of 25S (replicating) and 21S (mature) SV40 DNA synthesized after cycloheximide treatment were always lower than those observed in an infected untreated control culture. This is consistent with a requirement for a protein(s) or for protein synthesis at the initiation step in SV40 DNA replication. The relative proportion of 25S DNA as compared with 21S viral DNA increased with increasing time after cycloheximide treatment. Removal of cycloheximide from inhibited cultures allowed the recovery of viral DNA synthesis to normal levels within 3 hr. During the recovery period, the ratio of 25S DNA to 21S DNA was 10 times higher than that observed after a 30-min pulse with (3)H-thymidine with an infected untreated control culture. The accumulation of 25S replicating SV40 DNA during cycloheximide inhibition or shortly after its removal is interpreted to mean that a protein(s) or protein synthesis is required to convert the 25S replicating DNA to 21S mature viral DNA. Further evidence of a requirement for protein synthesis in the 25S to 21S conversion was obtained by comparing the rate of this conversion in growing and resting cells. The conversion of 25S DNA to 21S DNA took place at a faster rate in infected growing cells than in infected confluent monolayer cultures. A temperature-sensitive SV40 coat protein mutation (large-plaque SV40) had no effect on the replication of SV40 DNA at the nonpermissive temperature.     

Late replicative intermediates are accumulated during simian virus 40 DNA replication in vivo and in vitro.

Simian virus 40 (SV40) replicating chromosomes were extracted from nuclei of infected cells. The chromosomes in the extract were resolved on neutral sucrose gradients, and the extent of replication of the DNA in the chromosome peaks was determined. The extract, in combination with cytosol factors and the appropriate precursors, supports the continued replication of viral DNA. The products of the incubation were mature form I DNA and molecules (after deproteinization) with sedimentation coefficients, in neutral sucrose, of 22S and 29S. The results of our analysis of this system indicate the following. (i) The 22S molecule, which has been described by previous workers, is a relaxed, replicating molecule and is an artifact of the in vitro system. (ii) When the in vitro synthesis is performed at optimal ionic strength (150 mM potassium acetate), the artifactual 22S molecule does not appear. (iii) Late replicative intermediates do accumulate in vivo and in vitro. The major late form accumulated is 91% completed. (iv) The replicating chromosomes can be resolved into two distinct peaks on neutral sucrose gradients. The molecules in these peaks differ in extent of replication. (v) The nuclear extraction procedure preferentially extracts early replicating chromosomes. The relevance of these data to the problem of SV40 and cellular chromosome replication and termination is described.     

DNA polymerase alpha is associated with replicating SV40 nucleoprotein complexes.

Simian virus 40 (SV40) nucleoprotein complexes were extracted from nuclei of infected monkey cells and fractionated on neutral sucrose density gradients. Complexes which contained replicating SV40 DNA (95S) separated well from those containing closed circular supercoiled viral DNA (75S). DNA polymerase activity was associated with the replicating nucleoprotein complexes but not with the slower sedimenting complexes. This DNA polymerase activity coprecipitated with the nucleoprotein complexes in the presence of MgCl2 and remained associated with the 95S complexes. This DNA polymerase activity has been identified as primarily DNA polymerase alpha on the basis of its sedimentation behavior, optimum salt concentration, and sensitivity to N-ethylmaleimide. DNA polymerase gamma activity was also detected in the complexes, but DNA polymerase beta was not associated with the complexes.     

DNA synthesis by partially purified replicating simian virus 40 chromosomes.

We have partially purified replicating simian virus 40 (SV40) chromosomes in a form which allows continued DNA synthesis in vitro. We first prepare a soluble DNA-synthesizing system from SV40-infected monkey cells and then sediment the components through a neutral sucrose gradient of extremely low ionic strength. Replicating SV40 chromosomes isolated from such gradients are capable of continuing DNA synthesis in vitro in the same manner as two crude subnuclear systems we have previously described (4). This indicates that the enzymes and other proteins required for in vitro DNA synthesis are bound to the replicating chromosomes.     

Immunoprecipitation of SV40 replicating minichromosomes complexed with bacteriophage T4 gene 32 protein.

Simian Virus 40 (SV40) DNA replication is a useful model to study eukaryotic cell DNA replication because it encodes only one replication protein and its genome has a nucleoprotein structure ('minichromosome') indistinguishable from cellular chromatin. Late after infection SV40 replicating DNA molecules represent about 5% of total viral minichromosomes. Since gene 32 protein (P32) from bacteriophage T4 interacts with single-stranded DNA and SV40 replication complexes are expected to contain single-stranded regions at the replication forks, we asked whether P32 might be used to isolate replicating SV40 minichromosomes. When nuclear extracts from SV40 infected cells were treated sequentially with P32 and anti-P32 antibodies, pulse-labeled minichromosomes were selectively immunoprecipitated. Agarose gel electrophoresis analysis confirmed that immunoprecipitated material corresponded to SV40 replicative intermediates. Protein analysis of the pelleted material revealed several proteins of viral and cellular origin. Among them, T antigen and histones were found to be complexed with at least other three proteins from cellular origin, to the replicative complexes. Additionally, anti-P32 antibodies were able to detect three cellular proteins of approximately 70, 32 and 13 kDa in western blots. These proteins could correspond to those found as part of an eukaryotic multisubunit single-stranded DNA binding protein. The use of P32 and anti-P32 antibodies thus allows the separation of replicating from mature SV40 minichromosomes and can constitute a novel method to enrich and to study replicative active chromatin.     

Analysis of simian virus 40 chromosome-T-antigen complexes: T-antigen is preferentially associated with early replicating DNA intermediates

The fraction and DNA composition of simian virus 40 chromosomes that were complexed with large T-antigens (T-Ag) were determined at the peak of viral DNA replication. Simian virus 40 chromatin containing radiolabeled DNA was extracted by the hypotonic method of Su and DePamphilis (Proc. Natl. Acad. Sci. U.S.A. 73:3466-3470, 1976) and then fractionated by sucrose gradient sedimentation into replicating (90S) and mature (70S) chromosomes. Viral chromosomes containing T-Ag were isolated by immunoprecipitation with saturating amounts of either an anti-T-Ag monoclonal antibody or an anti—T-Ag hamster serum under conditions that specifically precipitated T-Ag protein from cytosol extracts. An average of 10% of the uniformly labeled DNA in the 90S pool and 7.5% in the 70S pool was specifically precipitated, demonstrating that under these conditions immunologically reactive T-Ag was tightly bound to only 8% of the total viral chromosomes. In contrast, simian virus 40 replicating intermediates (RI) represented only 1.2% of the viral DNA, but most of these molecules were associated with T-Ag. At the shortest pulse-labeling periods, an average of 72 ± 18% of the radiolabeled DNA in 90S chromosomes could be immunoprecipitated, and this value rapidly decreased as the labeling period was increased. Electron microscopic analysis of the DNA before and after precipitation revealed that about 55% of the 90S chromosomal RI and 72% of the total RI from both pools were specifically bound to T-Ag. Comparison of the extent of replication with the fraction of RI precipitated revealed a strong selection for early replicating DNA intermediates. Essentially all of the RI in the 70S chromosomes were less than 30% replicated and were precipitated with anti—T-Ag monoclonal antibody or hamster antiserum. An average of 88% of the 90S chromosomal RI which were from 5 to 75% replicated were immunoprecipitated, but the proportion of RI associated with T-Ag rapidly decreased as replication proceeded beyond 70% completion. By the time sibling chromosomes had separated, only 3% of the newly replicated catenated dimers in the 90S pool (<1% of the dimers in both pools) were associated with T-Ag. Measurements of the fraction of radiolabeled DNA in each quarter of the genome confirmed that T-Ag was preferentially associated with newly initiated molecules in which the nascent DNA was nearest the origin of replication. These results are consistent with a specific requirement for the binding of T-Ag to viral chromosomes to initiate DNA replication, and they also demonstrate that T-Ag does not immediately dissociate from chromosomes once replication begins. The biphasic relationship between the fraction of T-Ag—containing RI and the extent of DNA replication suggests either that 1 or 2 molecules of T-Ag remain stably bound until replication is about 70% completed or that 4 to 6 molecules of T-Ag are randomly released from each RI at a uniform rate throughout replication.     

Electron microscope localization of a protein bound near the origin of simian virus 40 DNA replication.

A salt-stable complex of protein and viral DNA obtained from Simian virus 40 (SV40)-infected monkey cells or mature SV40 virions has a novel structure. When viewed by high resolution electron microscopy, the circular SV40 DNA molecule has bound to it one to three globular protein "knobs". Using ecoRI and hpaII restriction endonucleases, each of which can cleave SV40 DNA once at a known location (10, 11, 12, 14), the bound protein can be localized at 0.7 plus or minis 0.05 on the SV40 DNA physical map (SV40 fractional length, clockwise from the ecoRI endonuclease-cleavage site).     

Structural organization of human simian virus 40 chromosomes. I. Heterogeneity and composition of nuclear DNA-protein complexes at different stages of lytic infection

Extraction of the purified nuclei of SV40 infected cells reveals a heterogeneous set of viral DNA-protein complexes. Earlier, the authors have shown the possibility of nuclear particles extraction being indistinguishable from mature SV40 virions. In the present work, structural intermediates of virus maturation from free minichromosomes through replicative complexes to immature virion particles have been analyzed. The fractionation of viral complexes by non-denaturing agarose gel electrophoresis has been employed. The protein composition of the complexes as determined by two-dimensional gel electrophoresis indicates that five histone fractions including H1 are present during minichromosome maturation to the chromosome of the mature virion.     

Nucleoprotein Complexes Containing Replicating Simian Virus 40 DNA: Comparison with Polyoma Nucleoprotein Complexes

Procedures for isolating nucleoprotein complexes containing replicating polyoma DNA from infected mouse cells were used to prepare short-lived nucleoprotein complexes (r-SV40 complexes) containing replicating simian virus 40 (SV40) DNA from infected monkey cells. Like the polyoma complexes, r-SV40 complexes were only partially released from nuclei by cell lysis but could be extracted from nuclei by prolonged treatment with solutions containing Triton X-100. r-SV40 complexes sedimented faster than complexes containing SV40 supercoiled DNA (SV40 complex) in sucrose gradients, and both types of SV40 nucleoprotein complexes sedimented ahead of polyoma complexes containing supercoiled polyoma DNA (py complex). The sedimentation rates of py complex and SV40 complex were 56 and 61S, respectively, based on the sedimentation rate of the mouse large ribosomal subunit as a marker. r-SV40 complexes sedimented as multiple peaks between 56 and 75S. Sedimentation and buoyant density measurements indicated that protein is bound to all forms of SV40 DNA at about the same ratio of protein to DNA (1-2/1) as was reported for polyoma nucleoproteins.     

Species specificity of simian virus 40 DNA replication in vitro requires multiple functions of human DNA polymerase alpha

Human cell extracts support the replication of SV40 DNA, whereas mouse cell extracts do not. Species specificity is determined at the level of initiation of DNA replication, and it was previously found that this requires the large subunit, p180, of DNA polymerase alpha-primase to be of human origin. Furthermore, a functional interaction between SV40 large T antigen (TAg) and p180 is essential for viral DNA replication. In this study we determined that the N-terminal regions of human p180, which contain the TAg-binding sites, can be replaced with those of murine origin without losing the ability to support SV40 DNA replication in vitro. The same substitutions do not prevent SV40 TAg from stimulating the activity of DNA polymerase alpha-primase on single-stranded DNA in the presence of replication protein A. Furthermore, biophysical studies show that the interactions of human and murine DNA polymerase alpha-primase with SV40 TAg are of a similar magnitude. These studies strongly suggest that requirement of SV40 DNA replication for human DNA polymerase alpha depends neither on the TAg-binding site being of human origin nor on the strength of the binary interaction between SV40 TAg and DNA polymerase alpha-primase but rather on sequences in the C-terminal region of human p180.     

Discrete regions of simian virus 40 large T antigen are required for nonspecific and viral origin-specific DNA binding.

The nondefective adenovirus type 2 (Ad2)-simian virus 40 (SV40) hybrid viruses, Ad2+ND2 and Ad2+ND4, have been used to determine which regions of the SV40 genome coding for the large tumor (T) antigen are involved in specific and nonspecific DNA binding. Ad2+ND2 encodes 45,000 M4 (45K) and 56,000 Mr (56K) T antigen-related polypeptides. The 45K polypeptide did not bind to DNA, but the 56K polypeptide bound nonspecifically to calf thymus DNA, Ad2+ND4 encodes 50,000 Mr (60K), 66,000 Mr (66K), 70,000 Mr (70K), 74,000 Mr (74K), and 90,000 Mr (90K) T antigen-related polypeptides, all of which bound nonspecifically to calf thymus DNA. However, in more stringent assays, where tight binding to viral origin sequences was tested, only the 90K protein specified by Ad2A+ND4 showed specific high affinity for sequences at the viral origin of replication. From these results and previously published experiments describing the SV40 DNA integrated into these hybrid viruses, it was concluded that SV40 early gene sequences located between 0.39 and 0.44 SV40 map units contribute to nonspecific DNA binding, whereas sequences located between 0.50 and 0.63 SV40 map units are necessary for specific binding to the viral origin of replication.     

A large-tumor-antigen-specific monoclonal antibody inhibits DNA replication of simian virus 40 minichromosomes in an in vitro elongation system.

In productively infected cells, a fraction of large-tumor antigen (T antigen) is tightly bound to replicating simian virus 40 (SV40) minichromosomes and does not dissociate at salt concentrations of greater than 1 M NaCl. We present electronmicrograms demonstrating the presence of T antigen on the replicated sections of replicating SV40 minichromosomes. We also show that the fraction of tightly bound T antigen is recognized by antibodies from mouse tumor serum and, more specifically, by a particular T-antigen-specific monoclonal antibody, PAb 1630. A second T-antigen-specific monoclonal antibody, PAb 101, does not react with the T-antigen fraction remaining on replicating SV40 chromatin at high salt concentrations. We used an in vitro replication system which allows, via semiconservative DNA replication, the completion of in vivo-initiated replicative intermediate DNA molecules. We show that monoclonal antibody PAb 1630, but not monoclonal antibody PAb 101, inhibits viral DNA replication. We discuss the possibility that SV40 T antigen may play a role in chain elongation during SV40 chromatin replication.