The origin of bidirectional DNA replication in polyoma virus.

The nucleotide locations of RNA-p-DNA covalent linkages in polyoma virus (PyV) replicating DNA were mapped in the region containing the genetically required origin of DNA replication (ori). These linkages mark the initiation sites for RNA-primed DNA synthesis. A clear transition was identified between the presence of these linkages (discontinuous DNA synthesis) and their absence (continuous DNA synthesis) on each strand of ori. This demonstrated that PyV DNA replication, like simian virus 40 (SV40), is semi-discontinuous, and thus revealed the location of the origin of bidirectional DNA replication (OBR). The transition site on the template encoding PyV late mRNA occurred at the junction of ori-core and T-antigen binding site A. This was essentially the same site as previously observed in SV40 (Hay and DePamphilis, 1982). However, in contrast to SV40, the transition site on the template encoding PyV early mRNA was displaced towards the late gene side of ori. This resulted in a 16 nucleotide gap within ori in which no RNA-p-DNA linkages were observed on either strand. A model for the initiation of PyV DNA replication is presented.     

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.     

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.     

Sequence-dependent DNA replication in preimplantation mouse embryos.

Circular, double-stranded DNA molecules were injected into nuclei of mouse oocytes and one- or two-cell embryos to determine whether specific sequences were required to replicate DNA during mouse development. Although all of the injected DNAs were stable, replication of plasmid pML-1 DNA was not detected unless it contained either polyomavirus (PyV) or simian virus 40 (SV40) DNA sequences. Replication occurred in embryos, but not in oocytes. PyV DNA, either alone or recombined with pML-1, underwent multiple rounds of replication to produce superhelical and relaxed circular monomers after injection into one- or two-cell embryos. SV40 DNA also replicated, but only 3% as well as PyV DNA. Coinjection of PyV DNA with either pML-1 or SV40 had no effect on the replicating properties of the three DNAs. These results are consistent with a requirement for specific cis-acting sequences to replicate DNA in mammalian embryos, in contrast to sequence-independent replication of DNA injected into Xenopus eggs. Furthermore, PyV DNA replication in mouse embryos required PyV large T-antigen and either the alpha-beta-core or beta-core configuration of the PyV origin of replication. Although the alpha-core configuration replicated in differentiated mouse cells, it failed to replicate in mouse embryos, demonstrating cell-specific activation of an origin of replication. Replication or expression of PyV DNA interfered with normal embryonic development. These results reveal that mouse embryos are permissive for PyV DNA replication, in contrast to the absence of PyV DNA replication and gene expression in mouse embryonal carcinoma cells.     

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.     

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.     

Different regions of primase subunit p48 control mouse polyomavirus and simian virus 40 DNA replication in vitro

DNA polymerase alpha-primase (pol-prim), a complex consisting of four subunits, is the major species-specific factor for mouse polyomavirus (PyV) and simian virus 40 (SV40) DNA replication. Although p48 is the most conserved subunit of pol-prim, it is required for in vitro PyV DNA replication but can inhibit cell-free SV40 DNA replication. Production of chimeric human-mouse p48 revealed that different regions of p48 are involved in supporting PyV DNA replication and inhibiting SV40 DNA replication. The N and C-terminal parts of p48 do not have species-specific functions in cell-free PyV DNA replication, but the central part (amino acids [aa] 129 to 320) controls PyV DNA replication in vitro. However, PyV T antigen physically binds to mouse, human, and chimeric pol-prim complexes independently, whether they support PyV DNA replication or not. In contrast to the PyV system, the inhibitory effects of mouse p48 on SV40 DNA replication are mediated by N- and C-terminal regions of p48. Thus, a chimeric p48 containing human aa 1 to 128, mouse aa 129 to 320, and human aa 321 to 418 is active in both PyV and SV40 DNA replication in vitro.     

Papillomavirus contains cis-acting sequences that can suppress but not regulate origins of DNA replication.

Bovine papillomavirus (BPV) DNA has been reported to restrict its own replication and that of the lytic simian virus 40 (SV40) origin to one initiation event per molecule per S phase, which suggests BPV DNA replication as a model for cellular chromosome replication. Suppression of the SV40 origin required two cis-acting BPV sequences (NCOR-1 and -2) and one trans-acting BPV protein. The results presented in this paper confirm the presence of two NCOR sequences in the BPV genome that can suppress polyomavirus (PyV) as well as SV40 origin-dependent DNA replication as much as 40-fold. However, in contrast to results of previous studies on SV40, most of the suppression of the PyV origin was due to NCOR-1, a 512-bp sequence that functioned independently of distance or orientation with respect to the PyV origin and that was not required for BPV DNA replication. Moreover, NCOR-1 alone or together with NCOR-2 did not restrict the ability of the PyV ori to reinitiate replication within a single S phase and did not require any BPV protein to exert suppression. Furthermore, NCOR-1 did not suppress BPV origin-dependent DNA replication except in the presence of PyV large tumor antigen (T-ag). Since NCOR-1 suppression of PyV origin activity also varied with T-ag concentration, suppression of origins by NCOR sequences appeared to require papovavirus T-ag. Therefore, it is unlikely that NCOR sequences are involved in regulating BPV DNA replication. When these results are taken together with those from other laboratories, BPV appears to be a slowly replicating version of papovaviruses rather than a model for origins of DNA replication in eukaryotic cell chromosomes.     

Initiation of simian virus 40 DNA replication in vitro: identification of RNA-primed nascent DNA chains.

Cell-free extracts of simian virus 40 (SV40)-infected CV-1 cells can initiate large tumor antigen dependent bidirectional replication in circular DNA molecules containing a functional SV40 origin of replication (ori). To determine whether or not DNA replication under these conditions involves RNA-primed DNA synthesis, replication was carried out in the presence of 5-mercuri-deoxycytidine triphosphate to label nascent DNA chains. Newly synthesized mercurated DNA was isolated by its affinity for thiol-agarose, and the 5'-ends of the isolated chains were radiolabeled to allow identification of RNA primers. At least 50% of the isolated chains contained 4 to 7 ribonucleotides covalently linked to their 5'-end; 80% of the oligoribonucleotides began with adenosine and 19% began with guanosine. About 60% of the nascent DNA chains annealed to the SV40 ori region, and about 80% of these chains were synthesized in the same direction as early mRNA. These results are consistent with the properties of SV40 DNA replication in vivo and support a model for initiation of SV40 DNA replication in which DNA primase initiates DNA synthesis on that strand of ori that encodes early mRNA.     

Initiation of JC virus DNA replication in vitro by human and mouse DNA polymerase alpha-primase.

Host species specificity of the polyomaviruses simian virus 40 (SV40) and mouse polyomavirus (PyV) has been shown to be determined by the host DNA polymerase alpha-primase complex involved in the initiation of both viral and host DNA replication. Here we demonstrate that DNA replication of the related human pathogenic polyomavirus JC virus (JCV) can be supported in vitro by DNA polymerase alpha-primase of either human or murine origin indicating that the mechanism of its strict species specificity differs from that of SV40 and PyV. Our results indicate that this may be due to differences in the interaction of JCV and SV40 large T antigens with the DNA replication initiation complex.     

Mapping of the 3'-end positions of simian virus 40 nascent strands

Using the instability of replication loops as the basis for the isolation of replication origins, we have undertaken an analysis of the 3' ends of the extruded nascent strands of replicating simian virus 40 (SV40) DNA. DNA fragments containing the SV40 origin of replication were obtained by digesting highly purified replicative intermediates of SV40 with BamHI and then heating at 55 degrees C for 16h. The origin-containing fragments extruded under these conditions were purified and cloned into pBR322. We used restriction mapping to analyze 640 clones of the 674 that contained SV40 sequences. A large majority of the clones were found to contain rearrangements in the sequences of either pBR322 or SV40 and were disregarded. Those clones that contained legitimate SV40 and pBR322 sequences were presumed to have been derived from the extruded SV40 nascent strands and were further analyzed. A combination of restriction enzymes was used that allowed us to define the 3' ends with an accuracy of +/- 20 base-pairs. The results of restriction analysis were confirmed by nucleotide sequence analysis of selected clones. The results show that the replication forks move with a high degree of symmetry, with respect to the initiation site of DNA replication, and are consistent with the existence of pause sites for the extension of replication forks. From the clones analyzed, it appears that the center of the replication bubble is to the early side of the BglI site.     

Sequence specificity for the initiation of RNA-primed simian virus 40 DNA synthesis in vivo

Analysis of the nucleotide sequences at the 5' ends of RNA-primed nascent DNA chains (Okazaki fragments) and of their locations in replicating simian virus 40 (SV40) DNA revealed the precise nature of Okazaki fragment initiation sites in vivo. The primary initiation site for mammalian DNA primase was 3'-purine-dT-5' in the DNA template and the secondary site was 3'-purine-dC-5', with the 5' end of the RNA primer complementary to either the dT or dC. The third position of the initiation site was variable with a preference for dT or dA. About 81% of the available 3'-purine-dT-5' sites and 20% of the 3'-purine-dC-5' sites were used. Purine-rich sites, such as PuPuPu and PyPuPu , were excluded. The 5'-terminal ribonucleotide composition of Okazaki fragments corroborated these conclusions. Furthermore, the length of individual RNA primers was not unique, but varied in size from six to ten bases with some appearing as short as three bases and some as long as 12 bases, depending on the initiation site used. This result was consistent with the average size (9 to 11 bases) of RNA primers isolated from specific regions of the genome. Excision of RNA primers did not appear to stop at the RNA-DNA junction, but removed a variable number of deoxyribonucleotides from the 5' end of the nascent DNA chain. Finally, only one-fourth of the replication forks contained an Okazaki fragment, and the distribution of their initiation sites between the two arms revealed that Okazaki fragments were initiated exclusively (99%) on retrograde DNA templates. The data obtained at two genomic sites about 350 and 1780 bases from ori were essentially the same as that reported for the ori region (Hay & DePamphilis , 1982), suggesting that the mechanism used to synthesize the first DNA chain at ori is the same as that used to synthesize Okazaki fragments throughout the genome.     

Initiation of SV40 DNA replication in vivo: location and structure of 5' ends of DNA synthesized in the ori region

Initiation sites for DNA synthesis were located at the resolution of single nucleotides in and about the genetically defined origin of replication (ori) in replicating SV40 DNA purified from virus-infected cells. About 50% of the DNA chains contained an oligoribonucleotide of six to nine residues covalently attached to their 5' ends. Although the RNA-DNA linkage varied, the putative RNA primer began predominantly with rA. The data reveal that initiation of DNA synthesis is promoted at a number of DNA sequences that are asymmetrically arranged with respect to ori: 5' ends of nascent DNA are located at several sites within ori, but only on the strand that also serves as the template for early mRNA, while 5' ends of nascent DNA with the opposite orientation are located only outside ori on its early gene side. This clear transition between discontinuous (initiation sites) and continuous (no initiation sites) DNA synthesis defines the origin of bidirectional replication at nucleotides 5210--5211 and demonstrates that discontinuous synthesis occurs predominantly on the retrograde arms of replication forks. Furthermore, it appears that the first nascent DNA chain is initiated within ori by the same mechanism used to initiate nascent DNA ("Okazaki fragments") throughout the genome.     

Initiation of simian virus 40 DNA replication in vitro: aphidicolin causes accumulation of early-replicating intermediates and allows determination of the initial direction of DNA synthesis.

Aphidicolin, a specific inhibitor of DNA polymerase alpha, provided a novel method for distinguishing between initiation of DNA synthesis at the simian virus 40 (SV40) origin of replication (ori) and continuation of replication beyond ori. In the presence of sufficient aphidicolin to inhibit total DNA synthesis by 50%, initiation of DNA replication in SV40 chromosomes or ori-containing plasmids continued in vitro, whereas DNA synthesis in the bulk of SV40 replicative intermediate DNA (RI) that had initiated replication in vivo was rapidly inhibited. This resulted in accumulation of early RI in which most nascent DNA was localized within a 600- to 700-base-pair region centered at ori. Accumulation of early RI was observed only under conditions that permitted initiation of SV40 ori-dependent, T-antigen-dependent DNA replication and only when aphidicolin was added to the in vitro system. Increasing aphidicolin concentrations revealed that DNA synthesis in the ori region was not completely resistant to aphidicolin but simply less sensitive than DNA synthesis at forks that were farther away. Since DNA synthesized in the presence of aphidicolin was concentrated in the 300 base pairs on the early gene side of ori, we conclude that the initial direction of DNA synthesis was the same as that of early mRNA synthesis, consistent with the model proposed by Hay and DePamphilis (Cell 28:767-779, 1982). The data were also consistent with initiation of the first DNA chains in ori by CV-1 cell DNA primase-DNA polymerase alpha. Synthesis of pppA/G(pN)6-8(pdN)21-23 chains on a single-stranded DNA template by a purified preparation of this enzyme was completely resistant to aphidicolin, and further incorporation of deoxynucleotide monophosphates was inhibited. Therefore, in the presence of aphidicolin, this enzyme could initiate RNA-primed DNA synthesis at ori first in the early gene direction and then in the late gene direction, but could not continue DNA synthesis for an extended distance.     

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.     

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.     

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.