The rolling circle . capsid complex as an intermediate in phi X DNA replication and viral assembly

Late in the life cycle of the single-stranded DNA phage phi X, the synthesis of positive strand DNA is coupled to the maturation of progeny virions. DNA synthesis and packaging take place in a replication-assembly complex, which we have purified to homogeneity and characterized. The following conclusions can be drawn: 1. The DNA component of the replication-assembly complex is a rolling circle with a single-stranded DNA tail which is less than or equal to genome length. 2. The major protein component of the replication-assembly complex is an intact viral capsid, as shown by gel analysis of 35S-labeled complexes. As replication proceeds at the DNA growing point, the positive strand tail of the rolling circle is displaced directly into the capsid. In addition to the capsid, the complex contains at least 1 molecule of the phi X gene A nicking protein, which appears to be covalently linked to the DNA. 3. The rolling circle . capsid complex can be purified to homogeneity by taking advantage of its uniform sedimentation velocity (35 S) and its uniform density upon equilibrium centrifugation in CsCl (1.50 g/cc). 4. The replication-assembly complex can be visualized in the electron microscope. An electron-dense particle, which has the dimensions of a viral capsid, is observed attached to a rolling circle at the DNA growing point. 5. Hybridization of specific phi X restriction fragments to the deproteinized, single-stranded tails of intact rolling circles has allowed the use of these replicating intermediates to determine both the origin/terminus and the direction of phi X positive strand DNA synthesis. The ends of the rolling circle tails map in the Hae III restriction Fragment Z6b, at the position on the phi X genome at which the gene A endonuclease is known to cut. This result indicates that this endonuclease participates in the "termination" of each round of synthesis by cutting off unit-length viral genomes. 6. Rolling circle . capsid complexes were also isolated from two other icosahedral, single-stranded DNA phages: G4 and St-1. The rolling circle . capsid complex seen in the case of the single-stranded DNA phages represents the first example of a structure in which DNA synthesis and viral assembly occur in a coupled manner. This tight coordination explains why double-stranded DNA circles are the net product of synthesis early in the viral life cycle while only single-stranded DNA circles are produced later. The single-stranded tails of the rolling circle intermediates are available for conversion to the duplex state at early times, whereas the concentration of preformed capsids later is high enough to bind to all of the replicating molecules and package the emerging positive strand DNA.     

Topology and replication of a nuclear episomal plasmid in the rodent malaria Plasmodium berghei

The rodent malaria Plasmodium berghei is one of a small number of species of Plasmodium that can currently be genetically transformed through experimentally controlled uptake of exogenous DNA by bloodstage parasites. Circular DNA containing a selectable marker replicates and is maintained under selection pressure in a randomly segregating episomal form during the first weeks after transformation. In this study, using pulsed field gel electrophoresis and ionising radiation, we show that in dividing asexual blood stage parasites the episomes are completely converted, within 2 weeks post-infection, into non-rearranged circular concatamers ranging in size between about 9 and 15 copies of the monomer. These occur as slow-moving aggregates held together by radiation-sensitive linkers consisting partly of single-stranded DNA. The process generating these complexes is not clear but 2D gel analysis showed that Cairns-type replication origins were absent and it seems most likely that the initial concatamerisation takes place using a rolling circle mechanism followed by circularisation through internal recombination. We propose a model in which continued rolling circle replication of the large circular concatamers and the recombinational activity of the tails of the rolling circles could lead to the formation of the large aggregates.     

Bacteriophage phi X174 RF DNA replication in vivo. A study by electron microscopy.

We have investigated bacteriophage φX174 RF ² DNA replication by electron microscopy. Three different, types of replicative intermediates were observed: rolling circles, partially duplex DNA circles and structures consisting of two DNA circles connected at a single point.Rolling circles with a single-stranded or partially double-stranded DNA tail were both observed. After cleavage of the rolling circles with the restriction endonuclease from Providentia stuartii 164 (PstI) the startpoint of rolling circle replication could be located at 21 map units from the PstI cleavage site in agreement with the previously determined position of the origin of φX RF DNA replication.Partially duplex DNA circles consist of circular viral DNA strands and incomplete complementary DNA strands. After cleavage of these molecules with PstI information about the startpoints of the synthesis of the complementary DNA strand was obtained.The connected DNA circles always contain one completely double-stranded DNA circle whereas the other circle consists of either single-stranded, partially duplex or completely duplex DNA.Part of the duplex-to-duplex DNA circles represent the well-known figure eight or catenated circular dimers. The other connected DNA circles presumably represent replication intermediates which arise by the association of the end of the genome length tail of the rolling circle with the origin-terminus region. This is suggested by the fact that the point of contact between the two DNA circles is located at approximately 21 map units from the Pst1 cleavage site, i.e. at the origin-terminus region of the φX genome. The connected DNA circles may be intermediates in the circularization and cleavage of the genome-length tail of the rolling circles in vivo.A model for φX174 RF DNA replication in vivo summarizing the data obtained by biochemical (Baas et al., 1978) and electron microscopic analysis of replicative intermediates is presented (Fig. 9).     

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

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

Topoisomerase II plays an essential role as a swivelase in the late stage of SV40 chromosome replication in vitro.

The effects of topoisomerases I and II on the replication of SV40 DNA were examined using an in vitro replication system of purified proteins that constitutes the monopolymerase system. In the presence of the two topoisomerases, two distinct nascent DNAs were formed. One product arising from the replication of the leading template strand was approximately half the size of the template DNA, whereas the other product derived from the lagging template strand consisted of short DNAs. These products were synthesized from both SV40 naked DNA and SV40 chromosomes. For the replication of SV40 naked DNA, either topoisomerase I or II maintained replication fork movement and supported complete leading strand synthesis. When SV40 chromosomes were replicated with the same proteins, reactions containing only topoisomerase I produced shorter leading strands. However, mature size DNA products accumulated in reactions supplemented with topoisomerase II, as well as in reactions containing only topoisomerase II. In the presence of crude extracts of HeLa cells, VP-16, a specific inhibitor of topoisomerase II, blocked elongation of the nascent DNA during the replication of SV40 chromosomes. These results indicate that topoisomerase II plays a crucial role as a swivelase in the late stage of SV40 chromosome replication in vitro.     

Replication of SV40 chromatin in extracts from eggs of Xenopus laevis.

Simian virus 40 (SV40) nucleoprotein complexes were prepared from lytically infected cells and used as primer-templates for DNA replication in protein extracts from Xenopus eggs. We found that nucleoprotein containing replicating SV40 DNA served as primer-template while nucleoprotein with nonreplicating SV40 DNA was ineffective. In vitro DNA synthesis begins with short DNA fragments ("Okazaki fragments") which are, in later steps, joined to give unit length SV40 DNA strands, suggesting that in vivo initiated rounds of replication are completed in vitro in the Xenopus system. This conclusion is supported by a restriction enzyme analysis showing that in vitro DNA synthesis occurs in fragments distal to the SV40 origin of replication. Our studies indicate that SV40 DNA replication in Xenopus extracts can be used an an experimental system to study the biochemistry of replicative DNA chain elongation in vitro.     

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

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

Preirradiation of host cells does not alter blockage of simian virus 40 replication forks by pyrimidine dimers

Do damage-inducible responses in mammalian cells alter the interaction of lesions with replication forks? We have previously demonstrated that preirradiation of the host cell mitigates UV inhibition of SV40 DNA replication; this mitigation can be detected within the first 30 min after the test irradiation. Here we test the hypotheses that this mitigation involves either (1) rapid dimer removal, (2) rapid synthesis of daughter strands past lesions (trans-dimer synthesis), or (3) continued progression of the replication fork beyond a dimer. Cells preirradiated with UV were infected with undamaged SV40, and the effects of UV upon viral DNA synthesis were measured within the first hour after a subsequent test irradiation. In preirradiated cells, as well as in non-preirradiated cells, pyrimidine dimers block elongation of daughter strands; daughter strands grow only to a size equal to the interdimer distance along the parental strands. There is, within this first hour after UV, no evidence for trans-dimer synthesis, nor for more rapid dimer removal either in the bulk of the parental DNA or in molecules in the replication pool. Progression of the replication forks was analyzed by electron microscopy of replicating SV40 molecules. Dimers block replication-fork progression in preirradiated cells to the same extent as in non-preirradiated cells. These experiments argue strongly against the hypotheses that preirradiation of host cells results in either the rapid removal of dimers, trans-dimer synthesis, or continued replication-fork progression beyond dimers.     

Architecture of the replication complex and DNA loops at the fork generated by the bacteriophage t4 proteins

Rolling circle replication has previously been reconstituted in vitro using M13 duplex circles containing preformed forks and the 10 purified T4 bacteriophage replication proteins. Leading and lagging strand synthesis in these reactions is coupled and the size of the Okazaki fragments produced is typical of those generated in T4 infections. In this study the structure of the DNAs and DNA-protein complexes engaged in these in vitro reactions has been examined by electron microscopy. Following deproteinization, circular duplex templates with linear tails as great as 100 kb are observed. The tails are fully duplex except for one to three single-stranded DNA segments close to the fork. This pattern reflects Okazaki fragments stopped at different stages in their synthesis. Examination of the DNA-protein complexes in these reactions reveals M13 duplex circles in which 64% contain a single large protein mass (replication complex) and a linear duplex tail. In 56% of the replicating molecules with a tail there is at least one fully duplex loop at the replication complex resulting from the portion of the lagging strand engaged in Okazaki fragment synthesis folding back to the replisome. The single-stranded DNA segments at the fork bound by gene 32 and 59 proteins are not extended but rather appear organized into highly compact structures ("bobbins"). These bobbins constitute a major portion of the mass of the full replication complex.     

Arrest of segregation leads to accumulation of highly intertwined catenated dimers: dissection of the final stages of SV40 DNA replication

When SV40-infected cells are placed into hypertonic medium, newly synthesized DNA accumulates as form C catenated dimers. These molecules consist of two supercoiled monomer circles of SV40 DNA interlocked by one or more topological inter-twinings and are seen as transiently labeled inter-mediates during normal replication. Form C catenated dimers represent pure segregation intermediates, replicative DNA structures in which DNA synthesis is complete but which still require topological separation of the two daughter circles. Hypertonic shock seems to block selectively a type II topoisomerase activity involved in disentangling the two circles. This is reflected in the fact that form C catenated dimers that accumulate during the block are highly intertwined with catenation linkage numbers up to C(L) = 20. While initiation of replication is also inhibited by hypertonic treatment, ongoing SV40 DNA synthesis is not affected, and replication is free to proceed from the earliest cairns structure through to form C catenated dimers. The block to segregation is rapidly and completely released by shifting the cells back to normal medium. A much slower recovery of DNA segregation takes place on prolonged incubation in hypertonic medium, perhaps because of some cellular homeostatic mechanism. The results of this work lead to a detailed view of the final stages of SV40 DNA replication.     

In vitro replication of DNA containing either the SV40 or the polyoma origin

The replication of DNA containing either the polyoma or SV40 origin has been done in vitro. Each system requires its cognate large-tumour antigen (T antigen) and extracts from cells that support its replication in vivo. The host-cell source of DNA polymerase alpha - primase complex plays an important role in discriminating between polyoma T antigen and SV40 T antigen-dependent replication of their homologous DNA. The SV40 origin- and T antigen-dependent DNA replication has been reconstituted in vitro with purified protein components isolated from HeLa cells. In addition to SV40 T antigen, HeLa DNA polymerase alpha - primase complex, eukaryotic topoisomerase I and a single-strand DNA binding protein from HeLa cells are required. The latter activity, isolated solely by its ability to support SV40 DNA replication, sediments and copurifies with two major protein species of 72 and 76 kDa. Although crude fractions yielded closed circular monomer products, the purified system does not. However, the addition of crude fractions to the purified system resulted in the formation of replicative form I (RFI) products. We have separated the replication reaction with purified components into multiple steps. In an early step, T antigen in conjunction with a eukaryotic topoisomerase (or DNA gyrase) and a DNA binding protein, catalyses the conversion of a circular duplex DNA molecule containing the SV40 origin to a highly underwound covalently closed circle. This reaction requires the action of a helicase activity and the SV40 T antigen preparation contains such an activity. The T antigen associated ability to unwind DNA copurified with other activities intrinsic to T antigen (ability to support replication of SV40 DNA containing the SV40 origin, poly dT-stimulated ATPase activity and DNA helicase).     

Activation of SV40 DNA replication in vitro by cellular protein phosphatase 2A.

We have made use of the cell-free SV40 DNA replication system to identify and characterize cellular proteins required for efficient DNA synthesis. One such protein, replication protein C (RP-C), was shown to be involved with SV40 large T antigen in the early stages of viral DNA replication in vitro. We demonstrate here that RP-C is identical to the catalytic subunit of cellular protein phosphatase 2A (PP2Ac). The purified protein dephosphorylates specific phosphoamino acid residues in T antigen, consistent with the hypothesis that SV40 DNA replication is regulated by modulating the phosphorylation state of the viral initiator protein. We also show that purified RP-C/PP2Ac preferentially stimulates SV40 DNA replication in extracts from early G1 phase cells. This finding suggests that the activity of a cellular factor that influences the net phosphorylation state of T antigen is cell cycle dependent.     

Nucleotide requirements for DNA replication of SV40 chromatin in digitonin-treated and saponin-treated permeable cells

Permeable cell systems have been developed by treatment with digitonin or saponin for studying in vitro DNA replication of chromatin. DNA replication of SV40 nucleoprotein complexes (SV40 chromatin) in these systems requires the addition of ATP, dCTP, dGTP, dTTP, and Mg2+. Further addition of three other ribonucleoside triphosphates slightly increased DNA synthesis. Omission of ATP greatly reduced DNA synthesis. In the presence of ATP, however, omission of dATP did not significantly alter or rather slightly enhanced DNA synthesis. Analysis of replicated SV40 DNA by gel electrophoresis and autoradiography indicated that complete replication of SV40 DNA and chromatin occurred in these systems     

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

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

SV40 DNA replication inhibition by the monofunctional DNA alkylator Et743

Ecteinascidin 743 (Et743) is a highly cytotoxic anticancer agent isolated from the squirt Ecteinascidia turbinate, which alkylates DNA in the minor groove at GC-rich sequences resulting in an unusual bending toward the major groove. The ability of Et743 to block DNA replication was studied using the well-established simian virus (SV40) model for mammalian DNA replication in cells and cell-free extracts. Intracellular SV40 DNA isolated from Et743-treated BSC-1 cells was analyzed by native, two-dimensional agarose gel electrophoresis. A low frequency of Et743 adducts detected at 30-100 nM drug concentrations inhibited SV40 origin activity and induced formation of unusual DNA replication intermediates. Under cell-free conditions, only a high Et743 adduct frequency reduced SV40 DNA synthesis. Comparative studies involving related DNA alkylators, tomamycin and saframycin A, revealed inhibition of SV40 DNA replication in cells at concentrations approximately 10 times higher than Et743. Under cell-free conditions tomamycin- or saframycin-A-adducted DNA templates inhibited DNA synthesis similarly to Et743. Et743 appears to be unusual among other alkylators, because its adducts strongly inhibit intracellular SV40 DNA replication but are relatively weak as cis inhibitors as measured under cell-free conditions.     

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.     

Structural topography of simian virus 40 DNA replication.

Applying an in situ cell fractionation procedure, we analyzed structural systems of the cell nucleus for the presence of mature and replicating simian virus 40 (SV40) DNA. Replicating SV40 DNA intermediates were tightly and quantitatively associated with the nuclear matrix, indicating that elongation processes of SV40 DNA replication proceed at this structure. Isolated nuclei as well as nuclear matrices were able to continue SV40 DNA elongation under replication conditions in situ, arguing for a coordinated and functional association of SV40 DNA and large T molecules at nuclear structures. SV40 DNA replication also was terminated at the nuclear matrix. While the bulk of newly synthesized, mature SV40 DNA molecules then remained at this structure, some left the nuclear matrix and accumulated at the chromatin.     

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.     

Coordinated regulation of replication protein A activities by its subunits p14 and p32

The heterotrimeric replication protein A (RPA) has multiple essential activities in eukaryotic DNA metabolism and in signaling pathways. Despite extensive analyses, the functions of the smallest RPA subunit p14 are still unknown. To solve this issue we produced and characterized a dimeric RPA complex lacking p14, RPADeltap14, consisting of p70 and p32. RPADeltap14 was able to bind single-stranded DNA, but its binding mode and affinity differed from those of the heterotrimeric complex. Moreover, in the RPADeltap14 complex p32 only minimally recognized the 3'-end of a primer in a primer-template junction. Partial proteolytic digests revealed that p14 and p32 together stabilize the C terminus of p70 against degradation. Although RPADeltap14 efficiently supported bidirectional unwinding of double-stranded DNA and interacted with both the simian virus 40 (SV40) large T antigen and cellular DNA polymerase alpha-primase, it did not support cell-free SV40 DNA replication. This inability manifested itself in a failure to support both the primer synthesis and primer elongation reactions. These data reveal that efficient binding and correct positioning of the RPA complex on single-stranded DNA requires all three subunits to support DNA replication.     

Identification of multiple cellular factors required for SV40 replication in vitro

The replication of simian virus 40 has been studied by using cell-free extracts derived from human 293 cells. Fractionation of this extract has led to the identification of three fractions that are required for efficient DNA synthesis. Initial fractionation of the crude extract by phosphocellulose chromatography has produced two fractions, I and II, neither of which is able to support replication separately, but when they are combined, efficient synthesis is restored. Both fractions are required, with SV40 T antigen, for the formation of a presynthesis complex at the SV40 origin. The major replication enzymes, DNA polymerase, DNA primase and the topoisomerases I and II all reside in fraction II. Fraction I has been subdivided into two subfractions (A and B) by DEAE-cellulose chromatography. Fraction A is essential for replication and is required for presynthesis complex formation. Fraction B stimulates DNA replication and is only required at the elongation stage. This multicomponent system has provided the foundation for identification of individual components that are required for DNA replication in vitro.