Maturation of newly replicated chromatin of simian virus 40 and its host cell

The DNA in replicating simian virus 40 chromatin and cellular chromatin was labeled with short pulses of [³H]thymidine. The structure of pulse-labeled nucleoprotein complexes was studied by micrococcal nuclease digestion. It was found that in both newly replicated viral and cellular chromatin, a structural state appears which is characterized by an increased sensitivity to nuclease and a faster than usual rate of cleavage to DNA fragments of monomeric nucleosome size and smaller. Pulse-chase experiments show that each of these effects requires a characteristic time to disappear in both systems, suggesting the existence of different sub-processes of chromatin maturation. One of these processes, detectable by the reversion of the unusually fast production of subnucleosomal fragments, is delayed in SV40 chromatin replication.     

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.     

Characterization of Simian virus 40 DNA component II during viral DNA replication

Replicating molecules of Simian virus 40 DNA labeled during a short pulse with [³H]thymidine have been fractionated by ultracentrifugation methods and the open circular form (DNA component II) has been characterized. The pulse-labeled DNA component II is a relatively small constituent (1 to 3%) of the pool of replicating molecules. Examination of the circular (18 S) and linear (16 S) strands of DNA component II by alkaline sedimentation and by degradation using exonuclease III of Escherichia coli reveals that the newly synthesized DNA is principally in the linear strand. Cleavage of pulse-labeled DNA component II by an fi⁺, R-factor restriction endonuclease from E. coli demonstrates that the interruption in the pulse-labeled strand is specifically located at the termination point for replication.During a chase period of 20 minutes the amount of DNA component II increases to about 6 to 8% of the total labeled viral DNA. The kinetics of formation of superhelical, DNA component I and disappearance of replicative intermediates are linear during the chase period. After several hours of continuous labeling of replicating viral DNA, the DNA component II pool consists mainly of molecules labeled in both strands with the interruption non-specifically located in either strand. These molecules probably arise by the random introduction of single-strand breaks in newly synthesized DNA component I. During short periods of continuous labeling with [³H]thymidine, the ratio of DNA components I to II increases as a function of the pulse duration. These results support a model for 8V 40 DNA replication in which the open circular form is a precursor of the superhelical form.     

Effects of VM26 (teniposide), a specific inhibitor of type II DNA topoisomerase, on SV40 DNA replication in vivo.

Simian Virus 40 (SV40) infected cells were pulse labeled with (3H) thymidine and chased either in the absence or in the presence of the cytotoxic drug VM26 (teniposide). We investigated the structure of labeled SV40 DNA and found that VM26 had no significant effect on replicative chain elongation but strongly inhibited the conversion of late replication intermediates to mature DNA daughter molecules. The late replicative SV40 DNA intermediates which accumulate in VM26 treated cells contained essentially full length labeled DNA strands. These newly synthesized strands were not part of two catenated interlocked SV40 monomers suggesting that the block occurred prior to the final ligation reaction. Since VM26 is known to be a specific inhibitor of DNA topoisomerase II we conclude that this enzyme is dispensable for the chain elongation of replicating SV40 DNA, but that it is essential for the termination of SV40 DNA replication cycles.     

In vitro synthesis of simian virus 40 DNA. II. Evidence for a repair mechanism.

The technique of density labeling of DNA by BrdU was used to characterize the material synthesized in vitro by cytoplasmic extracts of SV40 infected cells incubated in the presence of simian virus 40 (SV40) DNA component I molecules (Girard et al, Biochimie, this volume). In a first experiment, the template was labeled beforehand in vivo using [14C]-BrdU, and the in vitro incubation was carried out in the presence of [3H]-dGTP and [3H]-dTTP. In a second experiment, the template was labeled in vivo with 32P, and the in vitro incubation was in the presence of [3H]-dGTP and BrdUTP. After digestion with the restriction endonuclease Hind II + III, the fragments from the end products of the reaction were analyzed by density gradient centrifugation, at pH 7 and pH 13. In both experiments the DNA product molecules had the same density as the resepctive DNA templates. Cellular enzymes seem to be responsible for this in vitro synthesis of DNA, since cytoplasmic extracts from uninfected cells were almost as active as those from SV40 infected cells. The system was proved efficient in the conversion of "open circular" molecules (component II DNA molecules) to covalently closed circular DNA molecules (relaxed component I molecules). The use of DNA complexed with histones did not impart viral specificity to the system. It is concluded that the cytoplasmic extract is only capable of supporting the repair synthesis of added viral DNA.     

Preferential association of newly synthesized histones with replicating SV40 DNA.

The assembly of newly synthesized histones into nucleosomes during replication of SV40 minichromosomes in vivo was studied. Infected cells were labeled with 35S-methionine for a time shorter than that required to complete a round of viral DNA replication. Mature and replicating SV40 minichromosomes were extracted and separated by zonal sedimentation, and their histone content was analyzed by polyacrylamide gel electrophoresis (SDS and acidic urea). We show that the pulse-labeled histones associate preferentially with the replicating DNA.     

Replicative intermediates in UV-irradiated simian virus 40

We have used Simian virus 40 (SV40) as a probe to study the replication of UV-damaged DNA in mammalian cells. Viral DNA replication in infected monkey kidney cells was synchronized by incubating a mutant of SV40 (tsA58) temperature-sensitive for the initiation of DNA synthesis at the restrictive temperature and then adding aphidicolin to temporarily inhibit DNA synthesis at the permissive temperature while permitting pre-replicative events to occur. After removal of the drug, the infected cells were irradiated at 100 J/m2 (254 nm) to produce 6-7 pyrimidine dimers per SV40 genome, and returned to the restrictive temperature to prevent reinitiation of replication from the SV40 origin. Replicative intermediates (RI) were labeled with [3H]thymidine, and isolated by centrifugation in CsCl/ethidium bromide gradients followed by BND-cellulose chromatography. The size distribution of daughter DNA strands in RI isolated shortly after irradiation was skewed towards lengths less than the interdimer spacing in parental DNA; this bias persisted for at least 1 h after irradiation, but disappeared within 3 h, by which time the size of the newly-synthesized DNA exceeded the interdimer distance. No significant excision of dimers from parental strands in either replicative intermediates or Form I (closed circular) DNA molecules was detected. These data are consistent with the hypothesis that replication forks are temporarily blocked by dimers encountered on the leading strand side of the fork, but that daughter strand continuity opposite dimers is eventually established. Evidence was obtained for the generation at late times after irradiation, of Form I molecules in which the daughter DNA strands contain dimers. Thus DNA strand exchange as well as trans-dimer synthesis may be involved in the generation of supercoiled Form I DNA from UV-damaged SV40 replicative intermediates.     

Reinitiation of host DNA synthesis in senescent human diploid cells by infection with simian virus 40

Human diploid fibroblasts, TIG-1, cease to proliferate at about 60-62 population doubling level. In their senescent state used in this study, the percentage of nuclei labeled by [3H]thymidine for 48 h was around 1-2% in fresh medium containing 5-40% fetal bovine serum. The percentage of labelled nuclei increased up to 10-fold after infection with SV40. This increase reflects stimulation of cell DNA synthesis because: 1. The increase also occurred when ts A900 was used for infection at the non-permissive temperature, under these conditions viral DNA synthesis is inhibited; 2, the increase paralleled the stimulation of [3H]thymidine incorporation into DNA in a Hirt-precipitate fraction from SV40-infected cells. UV-irradiated SV40 had reduced ability to induce DNA synthesis. A viable deletion mutant of SV40, d1940, had almost the same activity to induce cell DNA synthesis as did wild-type SV40. Equilibrium density gradient centrifugation analysis of DNA labelled with 5-bromodeoxyuridine (BrdU) supported semiconservative replication rather than repair synthesis. We conclude that a considerable fraction of human diploid cells in a senescent population initiate host DNA replication by infection with SV40, although these cells cannot be stimulated with fetal bovine serum.     

Pulse-labeled, small closed circular DNA in cultured mouse and human cells

Mouse (erythroleukemia, TSA8, and FM3A) cells and human (HeLa and HL-60) cells were pulse-labeled with [3H]thymidine and covalently closed circular DNA in the extrachromosomal fraction was analyzed by fluorography following polyacrylamide gel electrophoresis. Two discrete bands for mouse and at least one, different, band for human cells emerged in the position to which small circular DNA (less than 1 kb) migrate, suggesting there to be species-specific, preferentially labeled, small circular DNA in mammalian cells. The incorporation of [3H]thymidine into the DNA was inhibited by cycloheximide but unaffected by aphidicolin. Restriction enzyme (AluI) digestion of the DNA fraction from MEL cells produced approximately 120-, 100-, and 50-bp labeled DNA fragments. The origin of the pulse-labeled DNAs is discussed.     

Adenovirus type 2 DNA replication. II. Termini of DNA replication.

Complete, mature adenovirus type 2 DNA molecules were isolated from virus-infected HeLa cells, pulse-labeled at 20 h postinfection in [3H]thymidine pulses shorter than the time necessary for one round of viral DNA replication. After digestion with the restriction endonucleases Eco RI, Hpa I, and Hind III, a temporal order of synthesis of different regions of the viral genome was established from the relative specific radioactivities in the restriction enzyme fragments. A comparison with the physical order of these fragments revealed the existence of two termini of DNA replication towards both the molecular right and left ends, respectively, of the viral chromosome.     

Maturation of replicating simian virus 40 DNA molecules in isolated nuclei by continued bidirectional replication to the normal termination region.

Mature SV40 DNA synthesized for different periods of time either in isolated nuclei or in intact cells was highly purified and then digested with restriction endonucleases in order to relate the time of synthesis of newly replicated viral DNA to its location in the genome. Replication in nuclei supplemented with a cytosol fraction from uninfected cells was a faithful continuation of the bidirectional process observed in intact cells, but did not exhibit significant initiation of new replicons. SV40 DNA replication in cells at 37 degrees C proceeded at about 145 nucleotides/min per replication fork. In the absence of cytosol, when DNA synthesis was limited and joining of Okazaki fragments was retarded, bidirectional SV40 DNA replication continued into the normal region where separation yeilded circular duplex DNA molecules containing one or more interruptions in the nascent DNA strands. In the presence of cytosol, this type of viral DNA was shown to be a precursor of covalently closed, superhelical SV40 DNA, the mature from of viral DNA.     

Structure of chromatin at deoxyribonucleic acid replication forks: location of the first nucleosomes on newly synthesized simian virus 40 deoxyribonucleic acid

Exonucleases specific for either 3' ends (Escherichia coli exonuclease III) or 5' ends (bacteriophage T7 gene 6 exonuclease) of nascent DNA chains have been used to determine the number of nucleotides from the actual sites of DNA synthesis to the first nucleosome on each arm of replication forks in simian virus 40 (SV40) chromosomes labeled with [3H]thymidine in whole cells. Whereas each enzyme excised all of the nascent [3H]DNA from purified replicating SV40 DNA, only a fraction of the [3H]DNA was excised from purified replicating SV40 chromosomes. The latter result was attributable to the inability of either exonuclease to digest nucleosomal DNA in native replicating SV40 chromosomes, as demonstrated by the following observations: (i) digestion with either exonuclease did not reduce the amount of newly synthesized nucleosomal DNA released by micrococcal nuclease during a subsequent digestion period; (ii) in briefly labeled molecules, as much as 40% of the [3H]DNA was excised from long nascent DNA chains; (iii) the fraction of [3H]DNA excised by exonuclease III was reduced in proportion to the actual length of the radiolabeled DNA; (iv) the effects of the two exonucleases were additive, consistent with each enzyme trimming only the 3' or 5' ends of nascent DNA chains without continued excision through to the opposite end. When the fraction of nascent [3H]DNA excised from replicating SV40 DNA by exonuclease III was compared with the fraction of [32P]DNA simultaneously excised from an SV40 DNA restriction fragment, the actual length of nascent [3H]DNA was calculated. From this number, the fraction of [3H]DNA excised from replicating SV40 chromosomes was converted into the number of nucleotides. Accordingly, the average distance from either 3' or 5' ends of long nascent DNA chains to the first nucleosome on either arm of replication forks was found to be 125 nucleotides. Furthermore, each exonuclease excised about 80% of the radiolabel in Okazaki fragments, suggesting that less than one-fifth of the Okazaki fragments were contained in nucleosomes. On the basis of these and other results, a model for eukaryotic replication forks is presented in which nucleosomes appear rapidly on both the forward and retrograde arms, about 125 and 300 nucleotides, respectively, from the actual site of DNA synthesis. In addition, it is proposed that Okazaki fragments are initiated on nonnucleosomal DNA and then assembled into nucleosomes, generally after ligation to the 5' ends of long nascent DNA chains is completed.     

Molecular analysis of enhanced replication of UV-damaged simian virus 40 DNA in UV-treated mammalian cells.

Irradiation of simian virus 40 (SV40)-infected cells with low fluences of UV light (20 to 60 J/m2, inducing one to three pyrimidine dimers per SV40 genome) causes a dramatic inhibition of viral DNA replication. However, treatment of cells with UV radiation (20 J/m2) before infection with SV40 virus enhances the replication of UV-damaged viral DNA. To investigate the mechanism of this enhancement of replication, we analyzed the kinetics of synthesis and interconversion of viral replicative intermediates synthesized after UV irradiation of SV40-infected cells that had been pretreated with UV radiation. This enhancement did not appear to be due to an expansion of the size of the pool of replicative intermediates after irradiation of pretreated infected cells; the kinetics of incorporation of labeled thymidine into replicative intermediates were very similar after irradiation of infected control and pretreated cells. The major products of replication of SV40 DNA after UV irradiation at the low UV fluences used here were form II molecules with single-stranded gaps (relaxed circular intermediates). There did not appear to be a change in the proportion of these molecules synthesized when cells were pretreated with UV radiation. Thus, it is unlikely that a substantial amount of DNA synthesis occurs past pyrimidine dimers without leaving gaps. This conclusion is supported by the observation that the proportion of newly synthesized SV40 form I molecules that contain pyrimidine dimers was not increased in pretreated cells. Pulse-chase experiments suggested that there is a more efficient conversion of replicative intermediates into form I molecules in pretreated cells. This could be due to more efficient gap filling in relaxed circular intermediate molecules or to the release of blocked replication forks. Alternatively, the enhanced replication observed here may be due to an increase in the excision repair capacity of the pretreated cells.     

Isolation and characterization of defective simian virus 40 genomes which complement for infectivity.

A new variant of simian virus 40 (EL SV40), containing the complete viral DNA separated into two molecules, was isolated. One DNA species contains nearly all of the early (E) SV40 sequences, and the other DNA contains nearly all of the late (L) viral sequences. Each genome was encircled by reiterated viral origins and termini and migrated in agarose gels as covalently closed supercoiled circles. EL SV40 or its progenitor appears to have been generated in human A172 glioblastoma cells, as defective interfering genomes during acute lytic infections, but was selected during the establishment of persistently infected (PI) green monkey cells (TC-7). PI TC-7/SV40 cells contained EL SV40 as the predominant SV40 species. EL SV40 propagated efficiently and rapidly in BSC-1, another line of green monkey cells, where it also formed plaques. EL SV40 stocks generated in BSC-1 cells were shown to be free of wild-type SV40 by a number of criteria. E and L SV40 genomes were also cloned in the bacterial plasmid pBR322. When transfected into BSC-1 cell monolayers, only the combination of E and L genomes produced a lytic infection, followed by the synthesis of EL SV40. However, transfection with E SV40 DNA alone did produce T-antigen, although at reduced frequency.     

Perturbations in simian virus 40 DNA synthesis by ultraviolet light.

Perturbations of Simian Virus 40 (SV40) DNA replication by ultraviolet (UV) light during the lytic cycle in permissive monkey CV-1 cells resemble those seen in host cell DNA replication. Formation of Form I DNA molecules (i.e. completion of SV40 DNA synthesis) was more sensitive to UV irradiation than synthesis of replicative intermediates or Form II molecules, consistent with inhibition of DNA chain elongation. The observed amounts of [3H]thymidine incorporated in UV-irradiated molecules could be predicted on the assumption that pyrimidine dimers are responsible for blocking nascent DNA strand growth. The relative proportion of labeled Form I molecules in UV-irradiated cultures rapidly increased to near-control values with incubation after 20 or 40 J/m2 of light (0.9--1.0 or 1.8--2.0 dimers per SV40 genome, respectively). This rapid increase and the failure of Form II molecules to accumulate suggest that SV40 growing forks can rapidly bypass many dimers. Form II molecules formed after UV irradiation were not converted to linear (Form III) molecules by the dimer-specific T4 endonuclease V, suggesting either that there are no gaps opposite dimers in these molecules or that T4 endonuclease V cannot use Form II molecules as substrates.     

Hyperthermia blocks DNA processing at the nuclear matrix

The capacity of control and heated HeLa cells to process newly polymerized DNA at the nuclear matrix was measured. DNA which had been pulse-labeled with [3H]thymidine was enriched by a factor of up to 6 at the cell's nuclear matrix. During continuous exposure to [3H]thymidine at 37 degrees C this enrichment for pulse-labeled DNA was reversed with a half-time of 7 min. We interpret this processing of newly replicated DNA to be a distribution of newly polymerized DNA throughout replicon-sized nuclear DNA domains. Both processing of newly polymerized DNA at the nuclear matrix and ligation of replicon clusters into the interphase cell chromosome were halted by incubation of cells at temperatures at or above 43 degrees C. When HeLa cells were pulse-labeled during a 30-min incubation at 45 degrees C and replaced at 37 degrees C, the enrichment for 3H-labeled DNA at the nuclear matrix was reversed with an initial half-time of 4 h. The results indicate that exposure of cells to hyperthermic temperatures blocks ongoing nascent DNA processing at the nuclear matrix and results in a retardation of DNA processing in preheated cells replaced at 37 degrees C.     

Distribution of Replicating Simian Virus 40 DNA in Intact Cells and Its Maturation in Isolated Nuclei

The maturation of replicating simian virus 40 (SV40) chromosomes into superhelical viral DNA monomers [SV40(I) DNA] was analyzed in both intact cells and isolated nuclei to investigate further the role of soluble cytosol factors in subcellular systems. Replicating intermediates [SV40(RI) DNA] were purified to avoid contamination by molecules broken at their replication forks, and the distribution of SV40(RI) DNA as a function of its extent of replication was analyzed by gel electrophoresis and electron microscopy. With virus-infected CV-1 cells, SV40(RI) DNA accumulated only when replication was 85 to 95% completed. These molecules [SV40(RI^*) DNA] were two to three times more prevalent than an equivalent sample of early replicating DNA, consistent with a rate-limiting step in the separation of sibling chromosomes. Nuclei isolated from infected cells permitted normal maturation of SV40(RI) DNA into SV40(I) DNA when the preparation was supplemented with cytosol. However, in the absence of cytosol, the extent of DNA synthesis was diminished three- to fivefold (regardless of the addition of ribonucleotide triphosphates), with little change in the rate of synthesis during the first minute; also, the joining of Okazaki fragments to long nascent DNA was inhibited, and SV40(I) DNA was not formed. The fraction of short-nascent DNA chains that may have resulted from dUTP incorporation was insignificant in nuclei with or without cytosol. Pulse-chase experiments revealed that joining, but not initiation, of Okazaki fragments required cytosol. Cessation of DNA synthesis in nuclei without cytosol could be explained by an increased probability for cleavage of replication forks. These broken molecules masqueraded during gel electrophoresis of replicating DNA as a peak of 80% completed SV40(RI) DNA. Failure to convert SV40(RI^*) DNA into SV40(I) DNA under these conditions could be explained by the requirement for cytosol to complete the gap-filling step in Okazaki fragment metabolism: circular monomers with their nascent DNA strands interrupted in the termination region [SV40(II^*) DNA] accumulated with unjoined Okazaki fragments. Thus, separation of sibling chromosomes still occurred, but gaps remained in the terminal portions of their daughter DNA strands. These and other data support a central role for SV40(RI^*) and SV40(II^*) DNAs in the completion of viral DNA replication.     

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.     

Formation and repair of DNA-protein crosslinks in newly replicated DNA

The production and removal of gamma-radiation-induced DNA-protein crosslinks (DPC) in nuclear matrix-associated newly replicated DNA were examined, as well as the relationship of DPC to DNA replication. In unirradiated, exponentially growing Chinese hamster V79 cells, DNA pulse labeled with [3H]thymidine was observed to be bound preferentially to protein. The pulse-labeled DNA subsequently became dissociated from protein. After a 30- to 60-min chase period, the level of labeled DNA in DPC was reduced to the same level as for bulk DNA. The radiation dose response for the formation of DPC was similar in newly replicated DNA that had been chased for various times and in mature chromatin DNA. Labeled DNA, in the DPC formed after 60 Gy, was rapidly removed from protein during the postirradiation incubation period. However, no recovery of DNA synthesis was observed, even after the majority of DPC were released. Thus either DPC are not the sole cause of the inhibition of DNA synthesis or their removal is not sufficient for DNA synthesis to resume.