Mapping an origin of DNA replication at a single-copy locus in exponentially proliferating mammalian cells

A general method for determining the physical location of an origin of bidirectional DNA replication has been developed recently and shown to be capable of correctly identifying the simian virus 40 origin of replication (L. Vassilev and E. M. Johnson, Nucleic Acids Res. 17:7693-7705, 1989). The advantage of this method over others previously reported is that it avoids the use of metabolic inhibitors, the requirement for cell synchronization, and the need for multiple copies of the origin sequence. Application of this method to exponentially growing Chinese hamster ovary cells containing the nonamplified, single-copy dihydrofolate reductase gene locus revealed that DNA replication begins bidirectionally in an initiation zone approximately 2.5 kilobases long centered about 17 kilobases downstream of the DHFR gene, coinciding with previously described early replicating sequences. These results demonstrate the utility of this mapping protocol for identifying cellular origins of replication and suggest that the same cellular origin is used in both the normal and the amplified DHFR locus.

Simian virus 40 origin auxiliary sequences weakly facilitate T-antigen binding but strongly facilitate DNA unwinding

The complete simian virus 40 (SV40) origin of DNA replication (ori) consists of a required core sequence flanked by two auxiliary sequences that together increase the rate of DNA replication in monkey cells about 25-fold. Using an extract of SV40-infected monkey cells that reproduced the effects of ori-auxiliary sequences on DNA replication, we examined the ability of ori-auxiliary sequences to facilitate binding of replication factors and to promote DNA unwinding. Although the replicationally active form of T antigen in these extracts had a strong affinity for ori-core, it had only a weak but specific affinity for ori-auxiliary sequences. Deletion of ori-auxiliary sequences reduced the affinity of ori-core for active T antigen by only 1.6-fold, consistent with the fact that saturating concentrations of T antigen in the cell extract did not reduce the stimulatory role of ori-auxiliary sequences in replication. In contrast, deletion of ori-auxiliary sequences reduced the efficiency of ori-specific, T-antigen-dependent DNA unwinding in cell extracts at least 15-fold. With only purified T antigen in the presence of topoisomerase I to unwind purified DNA, ori-auxiliary sequences strongly facilitated T-antigen-dependent DNA conformational changes consistent with melting the first 50 base pairs. Under these conditions, ori-auxiliary sequences had little effect on the binding of T antigen to DNA. Therefore, a primary role of ori-auxiliary sequences in DNA replication is to facilitate T-antigen-dependent DNA unwinding after the T-antigen preinitiation complex is bound to ori-core.

Transactivation of the adenovirus EIIa promoter in the absence of adenovirus E1A protein is restricted to mouse oocytes and preimplantation embryos

Undifferentiated mouse embryonal carcinoma (EC) cells are capable of transactivating the adenovirus EIIa promoter in the absence of its normal transactivator, E1A protein, suggesting that EC cells contain an E1A-like activity. In an effort to identify where this activity appears during normal mouse development, mouse oocytes and preimplantation embryos were injected with plasmids containing the EIIa promoter coupled to various reporter genes. These expression vectors were fully active in human 293 cells where E1A is present, but were inactive in differentiated fibroblast cell lines unless cotransfected with the E1A gene. In mouse oocytes and preimplantation embryos, EIIa promoter activity in the absence of adenovirus E1A protein was equivalent to or greater than activity of the HSV thymidine kinase promoter coupled to a strong enhancer. Coinjection of the E1A gene failed to stimulate EIIa activity further, perhaps because c-myc protein, which has been reported to transactivate this promoter, was already present at high levels in mouse oocytes. Activation of the EIIa promoter in the absence of E1A was unique to mouse oocytes and preimplantation embryos because gene expression from an EIIa promoter introduced into transgenic mice was observed only in the adult ovary, and particularly in the oocytes. In addition, post-implantation transgenic embryos failed to express the E1A-activatable reporter gene, thereby indicating that expression from the EIIa promoter is restricted to the relatively undifferentiated stages of oogenesis and preimplantation development. These data suggest that cellular promoters of the class that can be transactivated by E1A may serve uniquely to initiate transcription of genes that are needed for preimplantation development.

The need for enhancers in gene expression first appears during mouse development with formation of the zygotic nucleus

Microinjection of the firefly luciferase gene coupled to a thymidine kinase (tk) promoter provided a quantitative assay to evaluate the requirements for gene expression in individual mouse oocytes and embryos. Polyoma virus (PyV) enhancers had no effect on the level of gene expression or competition for transcription factors as long as the DNA remained either in the oocyte germinal vesicle or the pronuclei of one-cell embryos. Expression of injected genes could be observed in pronuclei because the signal that normally triggers zygotic gene expression in two-cell embryos still occurred in one-cell embryos arrested in S phase. However, when the tk promoter was injected into zygotic nuclei of two-cell embryos, enhancers increased the number of embryos that expressed luciferase as well as the level of luciferase activity per embryo. PyV enhancer mutation F101, selected for growth in mouse embryonal carcinoma F9 cells, stimulated expression in developing two-cell embryos about seven times better than the wild-type PyV enhancer and competed effectively for factors required for transcription. These results were consistent with the fact that enhancers are required to activate the PyV origin of DNA replication in developing two-cell embryos but not in one-cell embryos. The maximum levels of gene expression in oocytes, one-cell embryos, and developing two-cell embryos (1:67:21) were inversely related to the extent of chromatin assembly, but the need for enhancers was independent of chromatin assembly. Therefore, it appears that the need for enhancers to activate promoters or origins of replication results from some negative regulatory factor that first appears as a component of zygotic nuclear structure.

Sequences that promote formation of catenated intertwines during termination of DNA replication

The normal sequence at which SV40 DNA replication terminates (TER) is unusual in that it promotes formation of catenated intertwines when two converging replication forks enter to complete replication (Weaver et al., 1985). Here we show that yeast centromeric sequences also exhibit this phenomenon. CEN3 caused accumulation of late replicating intermediates and catenated dimers in plasmids replicating in mammalian cells, but only when it was located in the termination region (180 degrees from ori), and only when cells were subjected to hypertonic shock to reduce topoisomerase II activity. Therefore, formation of catenated intertwines during termination of DNA replication was sequence dependent, suggesting that topoisomerase II acts behind replication forks in the termination region to remove intertwines generated by unwinding DNA rather than acting after replication is completed and catenates are formed. Under normal physiological conditions, CEN3 did not promote formation of catenated dimers in either mammalian or yeast cells. Therefore, CEN does not maintain association of sister chromatids during mitosis in yeast by introducing stable catenated intertwines during replication.

The need for enhancers is acquired upon formation of a diploid nucleus during early mouse development

The activity of the polyoma virus (PyV) origin of DNA replication was used as a sensitive assay for enhancer function in one- and two-cell mouse embryos by injecting embryos with plasmid DNA containing different PyV ori configurations, allowing them to continue development in vitro, and then measuring plasmid DNA replication. Replication always required the PyV origin 'core' sequence in cis and PyV large tumor antigen (T-Ag) in trans. In developing two-cell embryos, DNA replication also required an enhancer in cis. Two copies of part of PyV enhancer 3 (beta element) was sevenfold better than one copy, and enhancer 3 was better than enhancer 1 + 2 (alpha element). Competition between ori configurations suggested that enhancers bound specific proteins required for replication and transcription. In contrast, DNA injected into one-cell embryos did not need an enhancer for replication, and no competition for replication factors was observed between different ori configurations. In fact, ori core replicated about ninefold better in one-cell embryos than the complete origin did in developing two-cell embryos. Therefore, core contains all the cis-acting information necessary to initiate DNA replication. Because one-cell embryos that replicated injected DNA retained their pronuclei and remained one-cell embryos, enhancers are not needed in mammalian development until a diploid nucleus is formed.

c-myc protein and DNA replication: separation of c-myc antibodies from an inhibitor of DNA synthesis

Antibodies against human c-myc protein have been reported to inhibit DNA polymerase activity and endogenous DNA synthesis in isolated nuclei, suggesting a role for c-myc in DNA replication. Using the same antibody preparations, we observed equivalent inhibition of simian virus 40 DNA replication and DNA polymerase alpha and delta activities in vitro, as well as inhibition of DNA synthesis in isolated nuclei. However, the c-myc antibodies could be completely separated from the DNA synthesis inhibition activity. c-myc antibodies prepared in other laboratories also did not interfere with initiation of simian virus 40 DNA replication, DNA synthesis at replication forks, or DNA polymerase alpha or delta activity. Therefore, the previously reported inhibition of DNA synthesis by some antibody preparations resulted from the presence of an unidentified inhibitor of DNA polymerases alpha and delta and not from the action of c-myc antibodies.

cis- and trans-acting sequences required for expression of simian virus 40 genes in mouse oocytes

To determine the requirements for gene expression in mammalian germ cells, circular double-stranded simian virus 40 (SV40) DNA molecules containing deletions in sequences controlling transcription and replication were injected into the nucleus of mouse oocytes. Expression of large (T-Ag) and small (t-Ag) tumor antigens ("early gene products") required at least three GGGCGG boxes, but did not require either the origin of viral DNA replication (ori) or a TATA box. Expression of capsid antigen VP1 ("late gene products") required at least three GGGCGG boxes, sequences between nucleotides 197 and 273 in the 72-bp repeat region, and transactivation by T-Ag. These results are consistent with the requirements for expression of the same genes in differentiated mammalian cells. Surprisingly, however, the 72-bp repeats ("enhancer elements") that are required for expression of T-Ag and t-Ag genes in differentiated cells were not required in mouse oocytes. Similarly, expression of both the early and late genes was unaffected in mouse oocytes by the absence of either DNA replication or an intact ori sequence, components required for maximum expression of late genes in differentiated cells. Thus, mammalian oocytes effectively utilize promoters that are fully active in mammalian differentiated cells only when associated with either enhancer elements or DNA replication. Furthermore, requirements for expression of SV40 genes in mouse oocytes are distinctly different from those reported for Xenopus oocytes. This suggests that caution should be exercised when extrapolating conclusions drawn from experiments with amphibian germ cells to mammalian germ cells.

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.

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.

In vitro initiation of DNA replication in simian virus 40 chromosomes

A soluble system has been developed that can initiate DNA replication de novo in simian virus 40 (SV40) chromatin isolated from virus-infected monkey cells as well as in circular plasmid DNA containing a functional SV40 origin of replication (ori). Initiation of DNA replication in SV40 chromatin required the soluble fraction from a high-salt nuclear extract of SV40-infected cells, a low-salt cytosol fraction, polyethylene glycol, and a buffered salts solution containing all four standard deoxyribonucleoside triphosphates. Purified SV40 large tumor antigen (T-ag) partially substituted for the high-salt nucleosol, and monoclonal antibodies directed against SV40 T-ag inhibited DNA replication. Replication began at ori and proceeded bidirectionally to generate replicating DNA intermediates in which the parental strands remained covalently closed, as observed in vivo. Partial inhibition of DNA synthesis by aphidicolin resulted in accumulation of newly initiated replicating intermediates in this system, a phenomenon not observed under conditions that supported completion of replication only. However, conditions that were optimal for initiation of replication repressed conversion of late-replicating intermediates into circular DNA monomers. Most surprising was the observation that p-n-butylphenyl-dGTP, a potent and specific inhibitor of DNA polymerase-alpha, failed to inhibit replication of SV40 chromatin under conditions that completely inhibited replication of plasmid DNA containing the SV40 ori and either purified or endogenous DNA polymerase-alpha activity. In contrast, all of these DNA synthesis activities were inhibited equally by aphidicolin. Therefore, DNA replication in mammalian cells is carried out either by DNA polymerase-alpha that bears a unique association with chromatin or by a different enzyme such as DNA polymerase-delta.

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.

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.

Selection of template initiation sites and the lengths of RNA primers synthesized by DNA primase are strongly affected by its organization in a multiprotein DNA polymerase alpha complex

Synthesis of (p)ppRNA-DNA chains by purified HeLa cell DNA primase-DNA polymerase alpha (pol alpha-primase) was compared with those synthesized by a multiprotein form of DNA polymerase alpha (pol alpha 2) using unique single-stranded DNA templates containing the origin of replication for simian virus 40 (SV40) DNA. The nucleotide locations of 33 initiation sites were identified by mapping G*pppN-RNA-DNA chains and identifying their 5'-terminal ribonucleotide. Pol alpha 2 strongly preferred initiation sites that began with ATP rather than GTP, thus frequently preferring different initiation sites than pol alpha-primase, depending on the template examined. The initiation sites selected in vitro, however, did not correspond to the sites used during SV40 DNA replication in vivo. Pol alpha 2 had the greatest effect on RNA primer size, typically synthesizing primers 1-5 nucleotides long, while pol alpha-primase synthesized primers 6-8 nucleotides long. These differences were observed even at individual initiation sites. Thus, the multiprotein form of DNA primase-DNA polymerase alpha affects selection of initiation sites, the frequency at which the sites are chosen, and length of RNA primers.

Expression of simian virus 40 early and late genes in mouse oocytes and embryos

Simian virus 40 (SV40) large- and small-tumor antigens (T-Ag, t-Ag) are normally synthesized early after infection of either permissive (monkey) or nonpermissive (mouse) fibroblasts, whereas an equivalent amount of viral coat protein (V-Ag) is observed late after infection of permissive cells and only after viral DNA replication has occurred. To determine whether or not expression of these genes is regulated in the same manner during early mammalian development, SV40 DNA was injected into the nuclei of mouse oocytes and one- and two-cell embryos. In oocytes, about three times more V-Ag was produced than T-Ag, and both were synthesized concomitantly in the same cells. Viral mRNA and proteins synthesized in oocytes comigrated during gel electrophoresis with the same products synthesized in SV40-infected monkey cells. Viral gene expression required circular DNA molecules injected into the nuclei of transcriptionally and translationally active cells. Injected DNA was stable and underwent conformational changes consistent with chromatin assembly. Oocytes did not replicate either polyomavirus or SV40 DNA. Thus, the temporal order of viral gene expression is circumvented in mouse germ cells, allowing these proteins to be expressed concurrently and in equivalent amounts with no requirement for DNA replication. However, in preimplantation embryos, neither T-Ag nor V-Ag was detected by immunoprecipitation although T-Ag synthesis was demonstrated as a specific requirement for SV40 DNA replication. Thus, viral gene expression in mouse embryos as early as the one-cell stage was reduced at least 500-fold relative to that in oocytes. Similarities between SV40 gene expression in mouse oocytes and that in Xenopus oocytes suggest that germ cells in higher animals share common regulatory mechanisms.

Persistence of DNA synthesis arrest sites in the presence of T4 DNA polymerase and T4 gene 32, 44, 45 and 62 DNA polymerase accessory proteins

DNA synthesis by phage T4 DNA polymerase is arrested at specific sequences in single-stranded DNA templates. To determine whether or not T4 DNA polymerase accessory proteins 32, 44, 45 and 62 eliminated recognition of these arrest sites, unique primer-templates were constructed in which DNA synthesis began at a DNA primer located at different distances from palindromic and nonpalindromic arrest sites. Nucleotide positions that caused polymerase to pause or leave the template were identified by sequence analysis of 5'-end labeled nascent DNA chains. Stable hairpin structures at palindromic sequences were confirmed by acetylation of single-stranded sequences with bromoacetaldehyde. Our results confirmed that these T4 DNA polymerase accessory proteins stimulated T4 DNA polymerase activity and processivity on natural as well as homopolymer primer-templates. However, they did not alter recognition of DNA synthesis arrest sites by T4 DNA polymerase. Extensive DNA synthesis resulted from an increased rate of translocation and/or processivity to the same extent over all DNA sequences.

DNA binding site for a factor(s) required to initiate simian virus 40 DNA replication

Efficient initiation of DNA replication in the absence of nonspecific DNA repair synthesis was obtained by using a modification of the system developed by J.J. Li and T.J. Kelly [(1984) Proc. Natl. Acad. Sci. USA 81, 6973-6977]. Circular double-stranded DNA plasmids replicated in extracts of CV-1 cells only when the plasmids contained the cis-acting origin sequence for simian virus 40 DNA replication (ori) and the extract contained simian virus 40 large tumor antigen. Competition between plasmids containing ori and plasmids carrying deletions in and about ori served to identify a sequence that binds the rate-limiting factor(s) required to initiate DNA replication. The minimum binding site (nucleotides 72-5243) encompassed one-half of the simian virus 40 ori sequence that is required for initiation of replication (ori-core) plus the contiguous sequence on the late gene side of ori-core containing G + C-rich repeats that facilitates initiation (ori-auxiliary). This initiation factor binding site was specific for the simian virus 40 ori region, even though it excluded the high-affinity large tumor antigen DNA binding sites.

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.

The termination region for SV40 DNA replication directs the mode of separation for the two sibling molecules

Separation of the two newly replicated chromosomes in simian virus 40 late replicating intermediates (RI*) occurred by two pathways. The parental DNA strands were completely unwound, releasing circular DNA monomers with a gap in the nascent strand (Form II*), or duplex DNA in the termination region was not unwound, resulting in formation of catenated dimers. Under optimal conditions, both products were transient intermediates in replication, although Form II* was predominant. However, in hypertonic medium both RI* and catenated dimers accumulated, and Form II* was not observed. Hypertonic medium appeared to inhibit both DNA unwinding in the termination region and separation of catenated dimers. When the size of the genome or the position of the origin of replication was changed, termination occurred at sites other than that of wild-type SV40. Neither catenated dimers nor RI* DNA accumulated at these sites. Instead, RI* separated into Form II*. Unwinding parental DNA was more difficult at some termination regions than others. Therefore, although completion of DNA replication does not require a unique termination sequence, this sequence can determine the mode of separation for sibling molecules.

DNA primase-DNA polymerase alpha from simian cells. Modulation of RNA primer synthesis by ribonucleoside triphosphates

DNA primase-DNA polymerase alpha, purified 53,000-fold from CV-1 cells, synthesized predominantly (p)ppA(pA)6-primed DNA on a poly(dT) template. About 80% of the RNA primers synthesized on an M13 DNA template were (p)ppA/G(pN)5-7, and 20% were (p)ppA/G(pN)0-4. RNA primer size was determined by gel electrophoresis after removing nascent DNA with phage T4 DNA polymerase 3'-5' exonuclease, leaving a single dNMP at the 3'-end of the RNA primer, and the terminal 5'-(p)ppN residue was determined by "capping" with [alpha-32P]GTP using vaccinia guanylyl-transferase. The processivity of DNA synthesis initiated by de novo synthesis of RNA primers was the same as that initiated on pre-existing RNA primers (10-15 dNMPs), although initiation on pre-existing primers was strongly preferred. Primers always began with A or G, even at high levels of CTP or UTP, although the ratio of A to G varied from 4:1 to 1:1 depending on the relative concentrations of ATP and GTP in the assay. ATP and GTP had no effect on primer length, but the fraction of shorter RNA primers increased 2-fold with higher concentrations of CTP or UTP. Nearest-neighbor analysis revealed a preference for purine ribonucleotides at RNA covalently linked to the 5'-end of DNA (RNA-p-DNA) junctions, and increasing the concentration of a single rNTP increased slightly its presence at RNA-p-DNA junctions. Thus, the base composition and size of RNA primers synthesized by DNA primase-DNA polymerase alpha is modulated by the relative concentrations of ribonucleoside triphosphates.

DNA primase-DNA polymerase alpha from simian cells: sequence specificity of initiation sites on simian virus 40 DNA

Unique single-stranded regions of simian virus 40 DNA, phage M13 virion DNA, and several homopolymers were used as templates for the synthesis of (p)ppRNA-DNA chains by CV-1 cell DNA primase-DNA polymerase alpha. Intact RNA primers, specifically labeled with an RNA capping enzyme, were typically 6 to 8 ribonucleotides long, although their lengths ranged from 1 to 9 bases. The fraction of intact RNA primers 1 to 4 ribonucleotides long was 14 to 73%, depending on the template used. RNA primer length varied among primers initiated at the same nucleotide, as well as with primers initiated at different sites. Thus, the size of an RNA primer depended on template sequence. Initiation sites were identified by mapping 5' ends of nascent RNA-DNA chains on the template sequence, identifying the 5'-terminal ribonucleotide, and partially sequencing one RNA primer. A total of 56 initiation events were identified on simian virus 40 DNA, an average of 1 every 16 bases. Some sites were preferred over others. A consensus sequence for initiation sites consisted of either 3'-dCTTT or 3'-dCCC centered within 7 to 25 pyrimidine-rich residues; the 5' ends of RNA primers were complementary to the dT or dC. High ATP/GTP ratios promoted initiation of RNA primer synthesis at 3'-dCTTT sites, whereas low ATP/GTP ratios promoted initiation at 3'-dCCC sites. Similarly, polydeoxythymidylic acid and polydeoxycytidylic acid were the only effective homopolymer templates. Thus, both template sequence and ribonucleoside triphosphate concentrations determine which initiation sites are used by DNA primase-DNA polymerase alpha. Remarkably, initiation sites selected in vitro were strikingly different from initiation sites selected during simian virus 40 DNA replication in vivo.

The role of palindromic and non-palindromic sequences in arresting DNA synthesis in vitro and in vivo

The nature of specific DNA sequences that arrest synthesis by mammalian DNA polymerase alpha in vitro was analyzed using circular, single-stranded M13 or phi X174 virion DNA templates annealed to a unique, terminally labeled, DNA primer. This method rigorously defined both the starting nucleotide position and the direction of synthesis, as well as making the amount of radioactivity proportional to the number rather than the length of nascent DNA chains. The precise nucleotide locations of arrest sites were determined over templates with complementary sequences by cloning unique DNA restriction fragments into M13 DNA and isolating virions containing either the Watson or Crick strand. Results were correlated with the locations of palindromic (self-complementary) sequences, repeated sequences, and repeated sequences with mirror-image orientation. Two classes of DNA synthesis arrest sites were identified, distinct in structure but equivalent in activity. Class I sites consisted of palindromic sequences that formed a stable hairpin structure in solution and arrested DNA polymerase on both complementary templates. The polymerase stopped precisely at the base of the duplex DNA stem, regardless of the direction from which the enzyme approached. Class II sites consisted of non-palindromic sequences that could not be explained by either secondary structure or sequence symmetry elements, and whose complementary sequence was not an arrest site. Size limits, orientation and some sequence specificity for arrest sites were suggested by the data. Arrest sites were also observed in vivo by mapping the locations of 3'-end-labeled nascent simian virus 40 DNA strands throughout the genome. Arrest sites closest to the region where termination of replication occurs were most pronounced, and the locations of 80% of the most prominent sites appeared to be recognized by alpha-polymerase on the same template in vitro. However, class I sites were not identified in vivo, suggesting that palindromic sequences do not form hairpin structures at replication forks.

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.

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.

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.

DNA polymerase alpha cofactors C1C2 function as primer recognition proteins

Most, if not all, of the DNA polymerase alpha activity in monkey and human cells was complexed with at least two proteins, C1 and C2, that together stimulated the activity of this enzyme from 180- to 1800-fold on low concentrations of denatured DNA, parvovirus DNA, M13, and phi X174 DNA or RNA-primed DNA templates, and poly(dT):oligo(dA) or oligo(rA). These primer-template combinations, which have from 200 to 5000 bases of template/primer, were then 7- to 50-fold more effective as substrates than DNase I-activated DNA. C1C2 specifically stimulated alpha polymerase, and only from the same cell type. Alpha X C1C2-polymerase reconstituted from purified alpha polymerase and the C1C2 cofactor complex behaved the same as native alpha X C1C2-polymerase and C1C2 had no effect on the sensitivity of alpha polymerase to aphidicolin, dideoxythymidine triphosphate, and N-ethylmaleimide. In the presence of substrates with a high ratio of single-stranded DNA template to either DNA or RNA primar, C1C2 increased the rate of DNA synthesis by decreasing the Km for the DNA substrate, decreasing the Km for the primer itself, increasing the use of shorter primers, and stimulating incorporation of the first deoxyribonucleotide. In contrast, C1C2 had no effect on the Km values for deoxyribonucleotide substrates (which were about 150-fold higher than for DNA replication in isolated nuclei), the ability of specific DNA sequences to arrest alpha polymerase, or the processivity of alpha polymerase. Accordingly, C1C2 function as primer recognition proteins. However, C1C2 did not reduce the comparatively high Km values or stimulate DNA synthesis by alpha polymerase on lambda DNA ends and DNase I-activated DNA, substrates with 12 and about 30-70 bases of template/primer, respectively. DNA restriction fragments with 1 to 4 bases of template/primer were substrates for neither alpha nor alpha X C1C2-polymerase. Therefore, we propose that C1C2 enhances the ability of alpha polymerase to initiate DNA synthesis by eliminating nonproductive binding of the enzyme to single-stranded DNA, allowing it to slide along the template until it recognizes a primer.

Preparation of DNA polymerase alpha X C1C2 by reconstituting DNA polymerase alpha with its specific stimulatory cofactors, C1C2

Essentially all of the DNA polymerase alpha activity in CV-1 monkey cells could be extracted as an enzyme complex that used DNA substrates with a low primer:template ratio, such as denatured DNA, at least 25 times more efficiently than did purified alpha polymerase. This form of the enzyme was rapidly dissociated either by the nonionic detergent Triton X-100 or by chromatography on phosphocellulose to generate alpha polymerase and its protein cofactor complex, C1C2. Both alpha polymerase and C1C2 were then independently purified free of deoxyribonuclease, RNA polymerase, DNA ligase, and ATPase activities, and the C1C2 complex was shown to consist of at least two proteins. Purified C1C2, which exhibited no DNA polymerase activity, completely restored the ability of alpha polymerase to use denatured DNA. Although high concentrations of denatured DNA inhibited the activity of C1C2, which binds tightly to single-stranded but not double-stranded DNA, low concentrations catalyzed reconstitution of alpha polymerase with C1C2. The resulting enzyme complex was chromatographically distinct from alpha polymerase on DEAE-Bio-Gel, was no longer dependent upon addition of C1C2 in order to utilize denatured DNA as effectively as DNase I-activated DNA, and was not inhibited by high concentrations of denatured DNA. These properties of the purified reconstituted enzyme were indistinguishable from those native alpha X C1C2-polymerase.

Structure of chromatin at deoxyribonucleic acid replication forks: nuclease hypersensitivity results from both prenucleosomal deoxyribonucleic acid and an immature chromatin structure

Relative to nonreplicating DNA in mature simian virus 40 (SV40) chromosomes, newly synthesized DNA in replicating SV40 chromosomes was found to be hypersensitive to the nonspecific endonucleases, micrococcal nuclease (MNase), DNase I, and DNase II. Nascent DNA, pulse labeled in either intact cells or nuclear extracts supplemented with cytosol, was digested about 5-fold faster and about 25% more extensively than uniformly labeled DNA in mature viral chromosomes. Pulse-chase experiments in vitro revealed a time-dependent chromatin maturation process that involved two distinct steps: (i) conversion of prenucleosomal DNA (PN-DNA) into immature nucleosomal oligomers and (ii) maturation of newly assembled chromatin into a structure with increased nuclease resistance. PN-DNA was hypersensitive to MNase, releasing short DNA fragments which were subsequently solubilized by the nuclease. However, when the nascent PN-DNA was specifically removed by digestion of replicating viral chromosomes with Escherichia coli exonuclease III (3'-5') and phage T7 exonuclease (5'-3'), subsequent digestion of the remaining chromatin with MNase revealed the same degree of hypersensitivity observed prior to exonuclease treatment. Furthermore, newly assembled nucleosomal oligomers, isolated after a brief MNase digestion of replicating viral chromosomes, were also hypersensitive to MNase relative to oligomers isolated from mature chromosomes. Hybridization analysis of the DNA in these immature oligomers revealed that it originated from both sides of replication forks. Inhibition of DNA polymerase alpha by aphidicolin inhibited conversion of PN-DNA into nucleosomes but did not inhibit loss of nucleosomal hypersensitivity to MNase. In contrast, components in the soluble fraction of the subcellular system ("cytosol") were required for both DNA replication and chromatin maturation. Analysis of the nucleoprotein products from a MNase digestion of replicating and mature SV40 chromosomes failed to detect a change in nucleosome structure that corresponded to the loss of nuclease hypersensitivity. However, the results presented demonstrate that both PN-DNA and newly assembled immature chromatin, present on both arms of SV40 replication forks, contribute to the commonly observed hypersensitivity of newly replicated chromatin to endonucleases.

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.

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.

Specific sequences in native DNA that arrest synthesis by DNA polymerase alpha

The effect of the DNA sequence of a template on the progress of DNA polymerase alpha was determined at the resolution of single nucleotides by using single-stranded, circular phi X174 DNA as a template and unique phi X 174 ONA fragments terminally labeled at their 3'-ends as primers. Therefore, the amount of radioactivity observed was always proportional to the number and not the length of nascent DNA chains. Extension of a primer by alpha-polymerase revealed that 3'-ends of nascent DNA chains accumulated at specific arrest sites consisting of GC-rich sequences of 1-8 bases distributed nonuniformly along the template with intervening sequences of 0-140 bases. The precise location and composition of these sites were determined by DNA sequencing methods, but a consensus sequence was not detected. However, the same pattern of arrest sites recognized by DNA polymerase alpha from CV-1 cells also arrested alpha-polymerase from HeLa cells, calf thymus tissue, and phage T4 DNA polymerase. An exception was DNA polymerase I from Escherichia coli which was insensitive to arrest signals. Analysis of recombinant DNA templates containing phi X174 DNA inserted into M13 DNA revealed that arrest sites were defined exclusively by those sequences within 24 bases upstream and 140 bases downstream of the arrest point; long range interactions between template sequences were not involved. One of the strongest arrest sites was located in the first two nucleotides at the base of the stem on the primer-proximal side of a stable hairpin structure, suggesting that such structures arrest the polymerase. However, only 28% of all arrest site nucleotides were found in this position; the rest were up to 25 bases upstream from any computer-predicted hairpin. Therefore, all arrest sites cannot be defined by secondary structure alone, although proximity to secondary structures may amplify normal variations in the rate of DNA elongation caused by primary sequences.

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.

Chromatin assembly. Relationship of chromatin structure to DNA sequence during simian virus 40 replication

The accessibility of five specific DNA sequences to six different single site restriction endonucleases was evaluated in replicating and mature simian virus 40 chromosomes isolated by three different methods. Electron microscopic and gel electrophoretic analysis of the DNA digestion products demonstrated that DNA accessibility in chromatin was established within 400 base pairs of replication forks and remained essentially unchanged during production of mature chromosomes and their subsequent re-entry into the replication pool. Saturating amounts of each enzyme reproducibly cut a fraction of the chromosomes, ranging from 13 to 49%. This is consistent with a nearly random phasing of chromatin structure. Examples in which all chromosomes were either cleaved or intact were never observed. Although variation in the accessibility of DNA sites near the origin of replication could be interpreted as preferred phasing in about 25% of the chromosomes, the finding that two isoschizomers, Hpa II and Msp I, did not cut chromosomes to the same extent precludes an unambiguous interpretation of the extents of cleavage of individual restriction enzymes. Since the extent of DNA cleavage observed at each restriction site was essentially indistinguishable in replicating as compared to mature chromosomes, the accessibility of DNA sequences near the origin is not obviously related to replication. Furthermore, the accessibility of DNA sites on one arm of a single replication fork was the same as the homologous sites on the other arm, consistent with a nearly random phasing of chromatin structure on both arms. This suggests that chromatin assembly occurs independently on the 2 sibling molecules of a single replicating chromosome.

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.

Preferred DNA sites are involved in the arrest and initiation of DNA synthesis during replication of SV40 DNA

Previous analysis of simian virus 40 (SV40) DNA replication revealed a 2-4 fold excess of DNA molecules that were 90 +/- 2% replicated, demonstrating that replication forks accumulate near the termination site. To determine whether replication is arrested at specific DNA sites, forks were located on the SV40 genome by specifically 32P labelling 3' ends of nascent DNA on purified replicating SV40 DNA, isolating the longest 32P-DNA chains, annealing them to SV40 DNA and then digesting them with a restriction endonuclease that cut near the terminatin site. 32P-DNA fragments of several discrete lengths were released, demonstrating that replication forks on native chromosomes were arrested at preferred sites on the DNA. Most forks were arrested when bidirectional DNA replication was 91% completed, and the two forks were separated by about 470 bp of unreplicated DNA centered at the expected termination site. Forks were also arrested at other locations such that the center of the termination region defined by DNA arrest sites varied by +/- 450 bp. Electron microscopic analysis of replicating DNA suggested that such variation may result from asynchronous arrival of some replication forks. Analysis of 5' end-labeled nascent DNA demonstrated that initiation of Okazaki fragments was also promoted at preferred DNA sites (about 100-120 per genome). Thus specific DNA sequences appear to be utilized throughout DNA replication, not just at the origin.

Structure, spacing, and phasing of nucleosomes on isolated forms of mature simian virus 40 chromosomes

Mature Simian virus 40 (SV40) chromosomes were isolated from infected CV-1 monkey cells by a hypotonic extraction method that not only allowed replicating viral chromosomes to faithfully continue DNA replication in vitro, but also was found to assemble nascent DNA into nucleosomes with a structure and arrangement typical of native viral chromosomes. Detailed analysis of the DNA and nucleoprotein products from micrococcal nuclease and DNase I digestion of mature viral chromosomes assembled in intact cells showed that the structure of SV40 and CV-1 cellular nucleosomes was the same. Furthermore, the histone composition of viral chromosome was indistinguishable from that of its host. In contrast to the identity in nucleosome structure, nucleosome spacing on isolated SV40 chromosomes was not as regular as on cellular chromatin. When 1% of the DNA was solubilized by micrococcal nuclease, as many as 20 cellular DNA bands were clearly resolved by gel electrophoresis, but only 6 to 7 viral DNA bands were observed and they were broader and less well resolved. In addition, micrococcal nuclease digested SV40 chromosomes at a faster initial rate and to a greater extent than CV-1 chromatin present in the same tube. Either BglI or EcoRI restriction endonuclease cut a single site in 30% of the SV40 chromosomes which suggested that viral nucleosomes were not located in a unique phase with respect to DNA sequence, but appeared to be randomly spaced around the genome. Viral chromosome structure was basically unaltered in hypotonically extracted chromosomes exposed to 200 or 600 mM NaCl and in isotonically extracted chromosomes prepared in the presence of Triton X-100 and EDTA. These results confirm and extend our previous data on the arrangement of SV40 nucleosomes inside isolated nuclei and demonstrate that the structure of viral chromosomes was not altered by the isolation procedures employed. The data are consistent with a model in which an average of 22 nucleosomes, randomly distributed around the SV40 genome, are separated by non-nucleosomal spacer regions which account for about 20% of the total DNA.

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.

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.

Involvement of eucaryotic deoxyribonucleic acid polymerases alpha and gamma in the replication of cellular and viral deoxyribonucleic acid

In an effort to identify the deoxyribonucleic acid (DNA) polymerase activities responsible for mammalian viral and cellular DNA replication, the effect of DNA synthesis inhibitors on isolated DNA polymerases was compared with their effects on viral and cellular DNA replication in vitro. DNA polymerase alpha, simian virus 40 (SV40) DNA replication in nuclear extracts, and CV-1 cell (the host for SV40) DNA replication in isolated nuclei all responded to DNA synthesis inhibitors in a quantitatively similar manner: they were relatively insensitive to 2',3'-dideoxythymidine 5'-triphosphate (d2TTP), but completely inhibited by aphidicolin, 1-beta-D-arabinofuranosylcytosine 5'-triphosphate (araCTP), and N-ethylmaleimide. In comparison, DNA polymerases beta and gamma were inhibited by d2TTP but insensitive to aphidicolin and 20--30 times less sensitive to araCTP than DNA polymerase alpha. Herpes simplex virus type 1 (HSV-1) DNA polymerase and DNA polymerase alpha were the only enzymes tested that were relatively insensitive to d2TTP; DNA polymerases beta and gamma, phage T4 and T7 DNA polymerases, and Escherichia coli DNA polymerase I were 100--250 times more sensitive. The results with d2TTP were independent of enzyme concentration, primer-template concentration, primer-template choice, and the labeled dNTP. A specific requirement for DNA polymerase alpha in the replication of SV40 DNA was demonstrated by the fact that DNA polymerase alpha was required, in addition to other cytosol proteins, to reconstitute SV40 DNA replication activity in N-ethylmaleimide-inactivated nuclear extracts containing replicating SV40 chromosomes. DNA polymerases beta and gamma did not substitute for DNA polymerase alpha. In contrast to SV40 and CV-1 DNA replication, adenovirus type 2 (Ad-2) DNA replication in isolated nuclei was inhibited by d2TTP to the same extent as gamma-polymerase. Ad-2 DNA replication was also inhibited by aphidicolin to the same extent as alpha-polymerase. Synthesis of CV-1 DNA, SV40 DNA, and HSV-1 DNA in intact CV-1 cells was inhibited by aphidicolin. Ad-2 DNA replication was also inhibited, but only at a 100-fold higher concentration. We found no effect of 2'-3'-dideoxythymidine (d2Thd) on cellular or viral DNA replication in spite of the fact that Ad-2 DNA replication in isolated nuclei was inhibited 50% by a ratio of d2TTP/dTTP of 0.02. This was due to the inability of CV-1 and Hela cells to phosphorylate d2Thd to d2TTP. These data are consistent with the hypothesis that DNA polymerase alpha is the only DNA polymerase involved in replicating SV40 DNA and CV-1 DNA and that Ad-2 DNA replication involves both DNA polymerases gamma and alpha.