Asymmetric Okazaki piece synthesis during replication of simian virus 40 DNA in vivo.

We have pulse-labeled simian virus 40 (SV40)-infected monkey cells with ³H-thymidine (³H-dThd) and have hybridized the viral Okazaki pieces (rapidly labeled short DNA chains found during DNA replication, < 250 nucleotides long) and SV40 “intermediate sized” DNA (longer nascent strands, up to full replicon size) to the separated strands of two SV40 DNA restriction fragments, one lying to either side of the origin of bidirectional DNA replication. As much as 5 fold more Okazaki piece DNA hybridized to one strand than to the other strand of each restriction fragment. The excess Okazaki piece DNA was in the strands oriented 3′ → 5′ away from the replication origin (the strands which are expected to be synthesized discontinuously). Neither the duration of the labeling period nor the temperature of the cells during labeling significantly altered this hybridization asymmetry. With respect to the hybridization of “intermediate sized” DNA, a reverse asymmetry was detected (1.7 fold more radioactivity in the strands oriented 5′ → 3′ away from the origin for a 1 min pulse label at 22°C). The effects on these hybridization asymmetries of preincubating the infected cells with FdUrd prior to pulse-labeling were also determined.We also measured the size of the Okazaki pieces using gel electrophoresis under denaturing conditons after releasing the pieces from the filter-bound DNA strands. The size distribution of the Okazaki piece DNA from each strand was the same (～ 145 nucleotides, weight average; 200–250 nucleotides, maximum size), indicating that the hybridization asymmetry resulted from a difference in the number rather than the size of the pieces in each strand.The simplest interpretation of our results is that SV40 DNA is synthesized semidiscontinuously: the strand with 3′ → 5′ orientation away from the origin is synthesized in short Okazaki pieces which are subsequently joined together, while the strand with 5′ → 3′ orientation away from the origin is synthesized continuously. Some models of two-strand discontinuous synthesis, however, cannot be ruled out.     

RNA primers in Simian virus 40 DNA replication. II. Distribution of 5' terminal oligoribonucleotides in nascent DNA.

A cell-free simian virus 40 (SV40) DNA replication system served to study the role of RNA in the initiation of nascent DNA chains of less than 200 nucleotides (Okazaki pieces). RNA-DNA covalent linkages were found to copurify with SV40 replicating DNA. These linkages were identified by transfer of a fraction of the ³²P from the 5′ position of a deoxyribonucleotide to 2′(3′)rNMPs upon either alkaline hydrolysis or RNAase T₂ digestion of SV40 replicating [³²P]DNA. Alkaline hydrolysis also exposed 5′ terminal hydroxyl groups in the nascent DNA which were detected as nucleosides after digestion with P1 nuclease. The RNA-DNA covalent linkages resulted from a population of Okazaki pieces containing uniquely sized oligoribonucleotides covalently attached to their 5′ termini (RNA primers). The density of a portion of the Okazaki pieces in potassium iodide gradients corresponded to a content of 90% DNA and 10% RNA, while the remaining Okazaki pieces appeared to contain only DNA. Incubation of Okazaki pieces with a defined length in the presence of either RNAase T₂ or potassium hydroxide converted about one-third to one-half of them intto a second well defined group of DNA chains of greater electrophoretic mobili y in polyacrylamide gels. The increased mobility corresponded to the removalof at least seven-residues. Since alkaline hydrolysis of similar Okazaki pieces revealed that one-third to one-half of them contained rN-³²P-dN linkages, the oligoribonucleotides must be covalently attached to the 5′ ends of nascent DNA chains. Although the significance of two populations of Okazaki pieces, one with and one without RNA primers, is imperfectly understood, a sizable fraction of nascent DNA chains clearly contained RNA primers.Neither the length of the RNA primer nor the number of RNA primers per DNA chain changed significantly with increasing length of Okazaki pieces. Since the frequency of RNA-DNA junctions found in nascent DNA chains greater than 400 nucleotides was similar to that of Okazaki pieces, the complete excision of RNA primers appears to occur after Okazaki pieces are joined to the 5′ end of growing daughter strands.³²P-label transfer analysis of Okazaki pieces recovered from hybrids with isolated HindII + III restriction fragments of SV40 DNA revealed a uniform distribution of rN-P-dN sequences around the replicating DNA molecule. Therefore, most, if not all, RNA primers serve to initiate Okazaki pieces rather than to initiate DNA replication at the origin of the genome. Moreover, the positions of RNA primers are not determined by a specific set of nucleotide sequences.     

Bacteriophage Mu DNA replication in vitro

An in vitro system for bacteriophage Mu DNA replication using lysates on cellophane discs is described. Mu replication was monitored by DNA hybridization. Using a thermoinducible Mu lysogen, 30-50% of all DNA synthesis in vitro was Mu-specific. Mu DNA synthesis is semidiscontinuous. In the presence of the DNA ligase inhibitor NMN, about one-half of the DNA was in Okazaki pieces and one-half in large DNA. The Mu Okazaki pieces hybridized mainly to the Mu light strand; the large DNA hybridized mainly to the Mu heavy strand. Okazaki pieces isolated from uninfected cells also hybridized to 2000-3000 bases of host DNA present in Mu-separated strands. However, the host Okazaki pieces hybridize to both Mu strands symmetrically. Most, if not all, host sequences were represented in mature Mu viral DNA. The in vitro data are most consistent with models in which Mu sequences, oriented randomly in both directions in the host chromosome, have recruited a bacterial replisome which traverses the Mu genome from left to right.     

Dispersive segregation of nucleosomes during replication of simian virus 40 chromosomes

The distribution of preformed ("old") histone octamers between the two arms of DNA replication forks was analyzed in simian virus 40(SV40)-infected cells following treatment with cycloheximide to prevent nucleosome assembly from nascent histones. Viral chromatin synthesized in the presence of cycloheximide was shown to be deficient in nucleosomes. Replicating SV40 DNA (wild-type 800 and capsid assembly mutant, tsB11) was radiolabeled in either intact cells or nuclear extracts supplemented with cytosol. Nascent nucleosomal monomers were then released by extensive digestion of isolated nuclei, nuclear extracts or isolated viral chromosomes with micrococcal nuclease. The labeled nucleosomal DNA was purified and found to hybridize to both strands of SV40 DNA restriction fragments taken from each side of the origin of DNA replication, whereas Okazaki fragments hybridized only to the strand representing the retrograde DNA template. In addition, isolated, replicating SV40 chromosomes were digested with two strand-specific exonucleases that excised nascent DNA from either the forward or the retrograde side of replication forks. Pretreatment of cells with cycloheximide did not result in an excess of prenucleosomal DNA on either side of replication forks, but did increase the amount of internucleosomal DNA. These data are consistent with a dispersive model for nucleosome segregation in which "old" histone octamers are distributed to both arms of DNA replication forks.     

Eukaryotic DNA replication. Enzymes and proteins acting at the fork

A complex network of interacting proteins and enzymes is required for DNA replication. Much of our present understanding is derived from studies of the bacterium Escherichia coli and its bacteriophages T4 and T7. These results served as a guideline for the search and the purification of analogous proteins in eukaryotes. model systems for replication, such as the simian virus 40 DNA, lead the way. Generally, DNA replication follows a multistep enzymatic pathway. Separation of the double-helical DNA is performed by DNA helicases. Synthesis of the two daughter strands is conducted by two different DNA polymerases: the leading strand is replicated continuously by DNA polymerase delta and the lagging strand discontinuously in small pieces by DNA polymerase alpha. The latter is complexed to DNA primase, an enzyme in charge of frequent RNA primer syntheses on the lagging strand. Both DNA polymerases require several auxiliary proteins. They appear to make the DNA polymerases processive and to coordinate their functional tasks at the replication fork. 3'----5'-exonuclease, mostly part of the DNA polymerase delta polypeptide, can perform proof-reading by excising incorrectly base-paired nucleotides. The short DNA pieces of the lagging strand, called Okazaki fragments, are processed to a long DNA chain by the combined action of RNase H and 5'----3'-exonuclease, removing the RNA primers, DNA polymerase alpha or beta, filling the gap, and DNA ligase, sealing DNA pieces by phosphodiester bond formation. Torsional stress during DNA replication is released by DNA topoisomerases. In contrast to prokaryotes, DNA replication in eukaryotes not only has to create two identical daughter strands but also must conserve higher-order structures like chromatin.     

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 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.     

Two-dimensional gel electrophoretic method for mapping DNA replicons.

We describe in detail a method which allows determination of the directions of replication fork movement through segments of DNA for which cloned probes are available. The method uses two-dimensional neutral-alkaline agarose gel electrophoresis followed by hybridization with short probe sequences. The nascent strands of replicating molecules form an arc separated from parental and nonreplicating strands. The closer a probe is to its replication origin or to the origin-proximal end of its restriction fragment, the shorter the nascent strands that are detected by the probe. The use of multiple probes allows determination of directions of replication fork movement, as well as locations of origins and termini. In this study, we used simian virus 40 as a model to demonstrate the feasibility of the method, and we discuss its applicability to other systems.     

Polyoma virus DNA replication is semi-discontinuous.

In marked contrast to simian virus 40 (SV40), polyoma virus (PyV) has been reported to replicate discontinuously on both arms of replication forks. In an effort to clarify the relationship between the mechanisms of DNA replication in these closely related viruses, the distribution of RNA-primed DNA chains at replication forks was examined concurrently in PyV and SV40 replicating DNA purified from virus-infected cells. About one third of PyV DNA chains contained 7 to 9 ribonucleotides covalently linked to their 5'-end. A similar fraction of DNA chains from replicating SV40 DNA contained an oligoribonucleotide that was 6 to 9 residues long and began with either (p)ppA or (p)ppG. Greater than 80% of PyV or SV40 RNA-primed DNA chains hybridized specifically to the retrograde template. Moreover, at least 95% of the RNA-primed DNA chains from either PyV or SV40 whose initiation sites could be mapped to unique nucleotide locations originated from the retrograde template. Therefore, PyV and SV40 DNA replication forks are essentially the same; DNA synthesis is discontinuous predominantly, if not exclusively, on the retrograde template.     

Emetine allows identification of origins of mammalian DNA replication by imbalanced DNA synthesis, not through conservative nucleosome segregation.

In the presence of emetine, an inhibitor of protein synthesis, nascent DNA on forward arms of replication forks in hamster cell lines containing either single or amplified copies of the DHFR gene region was enriched 5- to 7-fold over nascent DNA on retrograde arms. This forward arm bias was observed on both sides of the specific origin of bidirectional DNA replication located 17 kb downstream of the hamster DHFR gene (OBR-1), consistent with at least 85% of replication forks within this region emanating from OBR-1. However, the replication fork asymmetry induced by emetine does not result from conservative nucleosome segregation, as previously believed, but from preferentially inhibiting Okazaki fragment synthesis on retrograde arms of forks to produce 'imbalanced DNA synthesis'. Three lines of evidence support this conclusion. First, the bias existed in long nascent DNA strands prior to nuclease digestion of non-nucleosomal DNA. Second, the fraction of RNA-primed Okazaki fragments was rapidly diminished. Third, electron microscopic analysis of SV40 DNA replicating in the presence of emetine revealed forks with single-stranded DNA on one arm, and nucleosomes randomly distributed to both arms. Thus, as with cycloheximide, nucleosome segregation in the presence of emetine was distributive.     

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 DNA replication in nuclear monolayers.

Simian virus 40 DNA replication has been studied in nuclear monolayers prepared by treatment of monolayers of BSC-1 monkey kidney cells with Nonidet P-40. These nuclear monolayers incorporated [3H]TTP into two types of viral replicative intermediates that sediment as 25-26S and 22-23S species, respectively, in neutral sucrose gradients. The 22-23S species behaves, in dye buoyant density equilibrium gradients, as a late replicative intermediate. Examination of both species in alkaline sucrose gradients revealed the presence of two types of newly synthesized strands: (i) 4-7S strands and (ii) full-length, or nearly full-length, 10-16S strands. At low TTP concentrations (less than 0.5 muM), the two size classes were found in approximately equal amounts. However, at 10 to 50 muM TTP, the proportion of the longer strands increased, with a corresponding decrease in the relative amount of the 4-7S species. Thus, the joining of small, Okazaki-like fragments to the growing chain appears to require a much higher concentration of TTP than the synthesis of the fragments themselves. Replicating simian virus 40 DNA synthesized in the nuclear monolayers is is associated with "M bands", as previously demonstrated for replicating simian virus 40 DNA in cultured whole cells.     

Metabolism of Okazaki fragments during simian virus 40 DNA replication.

Essentially all of the Okazaki fragments on replicating Simian virus 40 (SV40)DNA could be grouped into one of three classes. Class I Okazaki fragments (about 20%) were separated from longer nascent DNA chains by a single phosphodiester bond interruption (nick) and were quantitatively identified by treating purified replicating DNA with Escherichia coli DNA ligase and then measuring the fraction of Okazaki fragments joined to longer nascent DNA chains. Similarly, class II Okazaki fragments (about 30%) were separated by a region of single-stranded DNA template (gap) that could be filled and sealed by T4 DNA polymerase plus E. coli DNA ligase, and class III fragments (about 50%) were separated by RNA primers that could be removed with E. coli DNA olymerase I, allowing the fragments to be joined with E. coli DNA ligase. These results were obtained with replicating SV40 DNA that had been briefly labeled with radioactive precursors in either intact cells or isolated nuclei. When isolated nuclei were further incubated in the presence of cytosol, all of the Okazaki fragments were converted into longer DNA strands as expected for intermediates in DNA synthesis. However, when washed nuclei were incubated in the abscence of cytosol, both class I and class II Okazaki fragments accumulated despite the excision of RNA primers: class III Okazaki fragments and RNA-DNA covalent linkages both disappeared at similar rates. These data demonstrate the existence of RNA primers in whole cells as well as in isolated nuclei, and identify a unique gap-filling step that is not simply an extension of the DNA chain elongation process concomitant with the excision of RNA primers. One or more factos found in cytosol, in addition to DNA polymerase alpha, are specifically involved in the gap-filling and ligation steps. The sizes of mature Okazaki fragments (class I) and Okazaki fragments whose synthesis was completed by T4 DNA polymerase were measured by gel electrophoresis and found to be broadly distributed between 40 and 290 nucleotides with an average length of 135 nucleotides. Since 80% and 90% of the Okazaments does not occur at uniformly spaced intervals along the DNA template. During the excision of RNA primers, nascent DNA chains with a single ribonucleotide covalently attached to the 5' terminus were identified as transient intermediates. These intermediates accumulated during excision of RNA primers in the presence of adenine 9-beta-D-arabinoside 5'-triphosphate, and those Okazaki fragments blocked by RNA primers (class III) were found to have originated the farthest from the 5' ends of long nascent DNA strands. Thus, RNA primers appear to be excised in two steps with the second step, removal of the final ribonucleotide, being stimulated by concomitant DNA synthesis. These and other data were used to construct a comprehensive metabolic pathway for the initiation, elongation, and maturation of Okazaki fragments at mammalian DNA replication forks.     

Self-annealing of 4 S strands from replicating simian virus 40 DNA

The nascent short strands (4 S) isolated from replicating Simian, virus 40 DNA hybridize specifically with denatured SV40 DNA and self-anneal extensively (70 to 92%) when incubated at 68 °C in 1 m-NaCl. Since complementary genetic sequences are present in the 4 S strands, both growing chains of SV40 DNA appear to be synthesized discontinuously at each replication fork.     

Coordinated leading- and lagging-strand synthesis at the Escherichia coli DNA replication fork. I. Multiple effectors act to modulate Okazaki fragment size.

The coordinated action of many enzymatic activities is required at the DNA replication fork to ensure the error-free, efficient, and simultaneous synthesis of the leading and lagging strands of DNA. In order to define the essential protein-protein interactions and model the regulatory pathways that control Okazaki fragment synthesis, we have reconstituted the replication fork of Escherichia coli in vitro in a rolling circle-type DNA replication system. In this system, in the presence of the single-stranded DNA binding protein, the helicase/primase function on the lagging-strand template is provided by the primosome, and the synthesis of DNA strands is catalyzed by the DNA polymerase III holoenzyme. These reconstituted replication forks synthesize equivalent amounts of leading- and lagging-strand DNA, move at rates comparable to those measured in vivo (600-800 nucleotides/s at 30 degrees C), and can synthesize leading strands in the range of 150-500 kilobases in length. Using this system, we have studied the cycle of Okazaki fragment synthesis at the replication fork. This cycle is likely to have several well defined decision points, steps in the cycle where incorrect execution by the enzymatic machinery will result in an alteration in the product of the reaction, i.e. in the size of the Okazaki fragments. Since identification of these decision points should aid in the determination of which of the enzymes acting at the replication fork control the cycle, we have endeavored to identify those reaction parameters that, when varied, alter the size of the Okazaki fragments synthesized. Here we demonstrate that some enzymes, such as the DnaB helicase, remain associated continuously with the fork while others, such as the primase, must be recruited from solution each time synthesis of an Okazaki fragment is initiated. We also show that variation of the concentration of the ribonucleoside triphosphates and the deoxyribonucleoside triphosphates affects Okazaki fragment size, that the control mechanisms acting at the fork to control Okazaki fragment size are not fixed at the time the fork is assembled but can be varied during the lifetime of the fork, and that alteration in the rate of the leading-strand DNA polymerase cannot account for the effect of the deoxyribonucleoside triphosphates.     

Swiveling and decatenation of replicating simian virus 40 genomes in vivo.

We have found that type II topoisomerase inhibitors have two effects on replicating simian virus 40 genomes in vivo: production of catenated dimers and slowed replication of the last 5% of the genome. This suggests that type II topoisomerase simultaneously decatenates and facilitates replication fork movement at this stage of DNA replication. On the basis of this observation, a detailed model is proposed for the roles of topoisomerases I and II in simian virus 40 DNA replication.     

Identification of the replicative intermediates in SV40 DNA replication in vitro.

The soluble replication system is which the exogenously added simian virus 40 (SV40) DNA can be replicated semiconservatively in vitro, has been developed (Ariga and Sugano, J.Virol. 48, 481, 1983). This paper further characterized the in vitro products synthesized on the cloned DNA containing the origin of SV40 DNA replication. The time course and pluse-chase experiments showed that the in vitro products were converted from the open circle to closed circles having the various superhelical densities, and finally to the twisted formI DNA seen in vivo by the analysis of agarose gel electrophoresis, alkaline sucrose gradient centrifugation, and density-transfer in isopycnic centrifugation. The replicative intermediates isolated after the short term incubation had replicated strands of the size smaller than the full length, most of which correspond to that of the putative Okazaki fragment. These and the previous results indicate that this in vitro system should be useful to investigate the molecular mechanism of SV40 DNA replication.     

Camptothecin, a specific inhibitor of type I DNA topoisomerase, induces DNA breakage at replication forks.

The structure of replicating simian virus 40 minichromosomes, extracted from camptothecin-treated infected cells, was investigated by biochemical and electron microscopic methods. We found that camptothecin frequently induced breaks at replication forks close to the replicative growth points. Replication branches were disrupted at about equal frequencies at the leading and the lagging strand sides of the fork. Since camptothecin is known to be a specific inhibitor of type I DNA topoisomerase, we suggest that this enzyme is acting very near the replication forks. This conclusion was supported by experiments with aphidicolin, a drug that blocks replicative fork movement, but did not prevent the camptothecin-induced breakage of replication forks. The drug teniposide, an inhibitor of type II DNA topoisomerase, had only minor effects on the structure of these replicative intermediates.     

Exposure to camptothecin breaks leading and lagging strand simian virus 40 DNA replication forks

To better understand aberrant simian virus 40 DNA replication intermediates produced by exposure of infected cells to the anticancer drug camptothecin, we compared them to forms produced by S1 nuclease digestion of normal viral replication intermediates. All of the major forms were identical in both cases. Thus the aberrant viral replicating forms in camptothecin-treated cells result from DNA strand breaks at replication forks. Linear simian virus 40 forms which are produced by camptothecin exposure during viral replication were identified as detached DNA replication bubbles. This indicates that double strand DNA breaks caused by camptothecin-topoisomerase I complexes occur at both leading and lagging strand replication forks in vivo.