Pausing in simian virus 40 DNA replication by a sequence containing (dG-dA)27.(dT-dC)27.

A 200 bp sequence including a stretch of 54 base pairs of alternating guanosine and adenosine nucleotide residues [(dG-dA)27.(dT-dC)27] was cloned in the simian virus 40 (SV40) genome between the KpnI and HpaII sites. This sequence was discovered earlier as part of a region limiting the amplification of sequences adjacent to an integrated polyoma virus in a transformed rat cell line. The newly constructed DNA was transfected into African Green monkey kidney CV1 cells and the variant virus was isolated by plaque-purification. The insertion was stably maintained and the variant virus grew more slowly than the wild type, had lower titers and gave smaller plaques. In mixed infection experiments, the variant was found to be stable, though the wild type replicated more rapidly. Pulse labeling experiments indicated that the unusual inserted sequence acts as a pause site for fork progression during DNA replication, as evidenced by the rate of incorporation of radioactively labeled nucleotides into various regions of the SV40 genome. Statistical fit of the experimental curves with theoretically generated curves suggested the pause of fork progression to be about one minute.     

Regulation of DNA replication by homopurine/homopyrimidine sequences

The simple repeating homopurine/homopyrimidine sequences dispersed throughout many eukaryotic genomes are known to form triple helical structures comprising three-stranded and single-stranded DNA. Several lines of evidence suggest that these structures influence DNA replication in cells. Homopurine/homopyrimidine sequences cloned into simian virus 40 (SV40) or SV40 origin-containing plasmids caused a reduced rate of DNA synthesis due to the pausing of replication forks. More prominent arrests were observed in in vitro experiments using single-stranded and double-stranded DNA with triplex-forming sequences. Nucleotides unable to form triplexes when present in the template DNA or when incorporated into the nascent strand prevented termination. Similarly, mutations destroying the triplex potential did not cause arrest while compensatory mutations restoring triplex potential restored it. These and other observations from a number of laboratories indicating that homopurine/homopyrimidine sequences act as arrest signals in vitro and as pause sites in vivo during replication fork movement suggest that these naturally occurring sequences play a regulatory role in DNA replication and gene amplification.     

Uncoupling of unwinding from DNA synthesis implies regulation of MCM helicase by Tof1/Mrc1/Csm3 checkpoint complex

The replicative DNA helicases can unwind DNA in the absence of polymerase activity in vitro. In contrast, replicative unwinding is coupled with DNA synthesis in vivo. The temperature-sensitive yeast polymerase alpha/primase mutants cdc17-1, pri2-1 and pri1-m4, which fail to execute the early step of DNA replication, have been used to investigate the interaction between replicative unwinding and DNA synthesis in vivo. We report that some of the plasmid molecules in these mutant strains became extensively negatively supercoiled when DNA synthesis is prevented. In contrast, additional negative supercoiling was not detected during formation of DNA initiation complex or hydroxyurea replication fork arrest. Together, these results indicate that the extensive negative supercoiling of DNA is a result of replicative unwinding, which is not followed by DNA synthesis. The limited number of unwound plasmid molecules and synthetic lethality of polymerase alpha or primase with checkpoint mutants suggest a checkpoint regulation of the replicative unwinding. In concordance with this suggestion, we found that the Tof1/Csm3/Mrc1 checkpoint complex interacts directly with the MCM helicase during both replication fork progression and when the replication fork is stalled.     

Polar arrest of the simian virus 40 tumor antigen-mediated replication fork movement in vitro by the tus protein-terB complex of Escherichia coli.

The effect of the tus protein-terB sequence complex of Escherichia coli on the movement of the SV40 large tumor antigen (T antigen)-mediated replication fork during SV40 DNA replication in vitro has been examined. In the monopolymerase and dipolymerase systems, the tus protein-terB complex efficiently blocked the replication fork movement in a polar fashion, as observed in prokaryotic replication systems. With crude cytosolic extracts of HeLa cells, the same polarity of fork arrest was observed, but the block of replication fork movement was inefficient. These results indicate that the structure of the prokaryotic tus protein-terB complex allows it to block replication fork movement in an orientation-dependent manner. We also show that the tus protein-terB complex blocks the 3'----5' helicase action of T antigen in a polar fashion, using substrates comprised of single-stranded M13 DNA with either a 52-base pair (bp) or 29-bp duplex containing the terB sequence. The tus protein-terB complex formed on the 52-bp duplex was less effective than the complex formed on the 29-bp duplex in blocking the helicase action of T antigen. With the 52-bp duplex substrate, T antigen movement was only partially (30%) blocked by the tus protein-terB sequence complex in the active orientation, whereas the E. coli dnaB helicase moving 5'----3' was blocked more than 90% by the complex in the active orientation. However, with the shorter 29-bp duplex substrate, the complex blocked the T antigen helicase activity about 75%, whereas the dnaB helicase activity was completely blocked. Altogether, these results suggest that the T antigen helicase activity, when coupled to DNA replication, is more susceptible to arrest by the tus protein-terB complex than the T antigen functioning as a helicase alone.     

Identification of cellular components required for SV40 DNA replication in vitro

To investigate the cellular proteins involved in simian virus 40 (SV40) replication, extracts derived from human 293 cells have been fractionated into multiple components. When such fractions are combined with the virus-encoded T antigen (TAg) and SV40 origin containing plasmid DNA, efficient and complete replication is achieved, while each fraction alone is inactive. At present, a minimum of eight such cellular components have been identified. Previous experiments have demonstrated one of these to be the cell-cycle-regulated proliferating-cell nuclear antigen (PCNA). As PCNA has been identified as a processivity factor for DNA polymerase δ, we suggest that both polymerases α and β are involved in this system. Three further fractions have been identified. One is a partially purified fraction which, under certain conditons, is required with TAg for the formation of a pre-synthesis complex of proteins at the replication origin. The second of these factors, RF-A, is a complex of three polypeptides which may function as a eucaryotic SSB. The third, RF-C, is a factor which is required, with PCNA, for coordinated leading- and lagging-strand synthesis at the replication fork. Complete synthesis and segregation of the daughter molecules also requires the presence of topoisomerases I and II. These results suggest a model for DNA synthesis which involves multiple stages prior to and during replicative DNA synthesis.     

(dT-dC)n and (dG-dA)n tracts arrest single stranded DNA replication in vitro.

Previous in vivo studies have indicated that (dT-dC)n.(dG-dA)n tracts (referred to here as (TC)n.(GA)n), which are widely dispersed in vertebrate genomes, may serve as pause or arrest signals for DNA replication and amplification. To determine whether these repeat elements act as stop signals for DNA replication in vitro, single stranded DNAs including (TC)n or (GA)n tracts of various lengths, were prepared by cloning such tracts into phage M13 vectors, and were replicated with the Klenow fragment of the E. coli DNA polymerase I, or with the calf thymus DNA polymerase alpha, by extension of an M13 primer. Gel electrophoresis of the reaction products revealed that the replication was specifically arrested around the middle of both (TC)n and (GA)n tracts of n greater than or equal to 16. However, whereas in the (TC)n tracts the arrests were less prominent at pH = 8.0 than at pH = 6.5-7.5, and were completely eliminated at pH = 8.5, the arrests in the (GA)n tracts were stronger at the higher pH values. These results, and previous data, suggest that the arrests were caused by formation of unusual DNA structures, possibly triple helices between partially replicated (TC)n or (GA)n tracts, and unreplicated portions of these sequences.     

Position and orientation-dependent effects of a eukaryotic Z-triplex DNA motif on episomal DNA replication in COS-7 cells.

A cluster of simple repeated sequences composed of 5'-(GC)5(AC)18(AG)21(G)9(CAGA)4GAGGGAGAGAGGCAGAGAGGG(AG)27-3 ' located near the origin of replication associated with the Chinese hamster dhfr gene has been shown to adopt multiple Z-form and triplex DNA structures under various experimental conditions (Bianchi, A., Wells, R. D., Heintz, N. H., and Caddle, M. S. (1990) J. Biol. Chem. 265, 21789-21796). Thus, we refer to the cluster of alternating repeats as a Z-triplex DNA motif. Primer extension studies indicate that DNA polymerases traverse the Z-triplex sequence more readily in the Z to triplex direction than in the triplex to Z direction. To examine the effect of these sequences on replication fork travel in living cells, the Z-triplex motif was cloned in both orientations on the early and late side of the SV40 origin of replication in the vector pSV011. Test constructs were cotransfected along with pSV011 into COS-7 cells, and plasmid replication was monitored by the accumulation of DpnI-resistant replication products. A single copy of the Z-triplex motif reduced plasmid replication after 48 h by 20-50%, depending upon the position and orientation of the insert relative to the SV40 origin sequences. The replication of plasmids containing two copies of the Z-triplex motif, in different orientations on either side of the SV40 origin, was reduced by 85-95% as compared to the cotransfected control. Two-dimensional gel analysis of replication intermediates failed to show absolute termination of replication fork travel at the Z-triplex sequences, but rather indicated that the Z-triplex region causes replication intermediates to accumulate during the late phases of replication. These results indicate that the dhfr Z-triplex region has complex effects on both replication fork movement and the termination phases of episomal DNA synthesis in animal cells.     

Visualization of DNA replication in the vertebrate model system DT40 using the DNA fiber technique

Maintenance of replication fork stability is of utmost importance for dividing cells to preserve viability and prevent disease. The processes involved not only ensure faithful genome duplication in the face of endogenous and exogenous DNA damage but also prevent genomic instability, a recognized causative factor in tumor development. Here, we describe a simple and cost-effective fluorescence microscopy-based method to visualize DNA replication in the avian B-cell line DT40. This cell line provides a powerful tool to investigate protein function in vivo by reverse genetics in vertebrate cells(1). DNA fiber fluorography in DT40 cells lacking a specific gene allows one to elucidate the function of this gene product in DNA replication and genome stability. Traditional methods to analyze replication fork dynamics in vertebrate cells rely on measuring the overall rate of DNA synthesis in a population of pulse-labeled cells. This is a quantitative approach and does not allow for qualitative analysis of parameters that influence DNA synthesis. In contrast, the rate of movement of active forks can be followed directly when using the DNA fiber technique(2-4). In this approach, nascent DNA is labeled in vivo by incorporation of halogenated nucleotides (Fig 1A). Subsequently, individual fibers are stretched onto a microscope slide, and the labeled DNA replication tracts are stained with specific antibodies and visualized by fluorescence microscopy (Fig 1B). Initiation of replication as well as fork directionality is determined by the consecutive use of two differently modified analogues. Furthermore, the dual-labeling approach allows for quantitative analysis of parameters that influence DNA synthesis during the S-phase, i.e. replication structures such as ongoing and stalled forks, replication origin density as well as fork terminations. Finally, the experimental procedure can be accomplished within a day, and requires only general laboratory equipment and a fluorescence microscope.     

Conformational Rearrangements of SV40 Large T Antigen during Early Replication Events

The Simian virus 40 (SV40) large tumor antigen (LTag) functions as the replicative helicase and initiator for viral DNA replication. For SV40 replication, the first essential step is the assembly of an LTag double hexamer at the origin DNA that will subsequently melt the origin DNA to initiate fork unwinding. In this study, we used three-dimensional cryo-electron microscopy to visualize early events in the activation of DNA replication in the SV40 model system. We obtained structures of wild-type double-hexamer complexes of LTag bound to SV40 origin DNA, to which atomic structures have been fitted. Wild-type LTag was observed in two distinct conformations: In one conformation, the central module containing the J-domains and the origin binding domains of both hexamers is a compact closed ring. In the other conformation, the central module is an open ring with a gap formed by rearrangement of the N-terminal regions of the two hexamers, potentially allowing for the passage of single-stranded DNA generated from the melted origin DNA. Double-hexamer complexes containing mutant LTag that lacks the N-terminal J-domain show the central module predominantly in the closed-ring state. Analyses of the LTag C-terminal regions reveal that the LTag hexamers bound to the A/T-rich tract origin of replication and early palindrome origin of replication elements are structurally distinct. Lastly, visualization of DNA density protruding from the LTag C-terminal domains suggests that oligomerization of the LTag complex takes place on double-stranded DNA.     

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.     

hDNA2 nuclease/helicase promotes centromeric DNA replication and genome stability

DNA2 is a nuclease/helicase that is involved in Okazaki fragment maturation, replication fork processing, and end resection of DNA double‐strand breaks. Similar such helicase activity for resolving secondary structures and structure‐specific nuclease activity are needed during DNA replication to process the chromosome‐specific higher order repeat units present in the centromeres of human chromosomes. Here, we show that DNA2 binds preferentially to centromeric DNA. The nuclease and helicase activities of DNA2 are both essential for resolution of DNA structural obstacles to facilitate DNA replication fork movement. Loss of DNA2‐mediated clean‐up mechanisms impairs centromeric DNA replication and CENP‐A deposition, leading to activation of the ATR DNA damage checkpoints at centromeric DNA regions and late‐S/G2 cell cycle arrest. Cells that escape arrest show impaired metaphase plate formation and abnormal chromosomal segregation. Furthermore, the DNA2 inhibitor C5 mimics DNA2 knockout and synergistically kills cancer cells when combined with an ATR inhibitor. These findings provide mechanistic insights into how DNA2 supports replication of centromeric DNA and give further insights into new therapeutic strategies.     

Relationship among location of T-antigen-induced DNA distortion,auxiliary sequences,and DNA replication efficiency

T-antigen-induced DNA distortion was studied in a series of simian virus 40 (SV40) plasmid constructs whose relative replication efficiency ranges from 0.2 to 36. Bending was detected in the wild-type SV40 regulatory region consisting of three copies of the GC-rich 21-bp repeat but not in constructs with only one or two copies of the 21-bp repeat. In a construct with enhanced replication efficiency, bending occurred in a 69-bp cellular sequence located upstream of a single copy of the 21-bp repeat. Bending occurred both upstream of ori and in the three 21-bp repeats located downstream of ori in a construct with reduced replication efficiency. In a construct with no 21-bp repeats, DNA distortion occurred downstream of ori. The results indicate that SV40 DNA replication is enhanced when the structure of the regulatory region allows the DNA to form a bent structure upstream of the initial movement of the replication fork.     

FANCM regulates DNA chain elongation and is stabilized by S‐phase checkpoint signalling

FANCM binds and remodels replication fork structures in vitro. We report that in vivo, FANCM controls DNA chain elongation in an ATPase‐dependent manner. In the presence of replication inhibitors that do not damage DNA, FANCM counteracts fork movement, possibly by remodelling fork structures. Conversely, through damaged DNA, FANCM promotes replication and recovers stalled forks. Hence, the impact of FANCM on fork progression depends on the underlying hindrance. We further report that signalling through the checkpoint effector kinase Chk1 prevents FANCM from degradation by the proteasome after exposure to DNA damage. FANCM also acts in a feedback loop to stabilize Chk1. We propose that FANCM is a ringmaster in the response to replication stress by physically altering replication fork structures and by providing a tight link to S‐phase checkpoint signalling.     

pZ189质粒DNA体外复制系统的建立

报道了含SV40复制起点的质粒DNA在真核细胞抽提物中进行复制的DNA体外复制系统的建立. 在外源性蛋白质SV40大T抗原(SV40 Tag)的参与下,穿梭质粒pZ189能在猴肾vero细胞胞浆抽提物中,利用其中参与体内DNA复制所需的蛋白质成分,有效地进行体外DNA复制. 从而为研究真核细胞DNA复制系统的结构与功能提供了简单、有效的模型.     

Initiation of simian virus 40 DNA replication in vitro.

Exogenously added simian virus 40 (SV40) DNA can be replicated semiconservatively in vitro by a mixture of a soluble extract of HeLa cell nuclei and the cytoplasm from SV40-infected CosI cells. When cloned DNA was used as a template, the clone containing the SV40 origin of DNA replication was active, but a clone lacking the SV40 origin was inactive. The major products of the in vitro reaction were form I and form II SV40 DNAs and a small amount of form III. DNA synthesis in extracts began at or near the in vivo origin of SV40 DNA synthesis and proceeded bidirectionally. The reaction was inhibited by the addition of anti-large T hamster serum, aphidicolin, or RNase but not by ddNTP. Furthermore, this system was partially reconstituted between HeLa nuclear extract and the semipurified SV40 T antigen instead of the CosI cytoplasm. It is clear from these two systems that the proteins containing SV40 T antigen change the nonspecific repair reaction performed by HeLa nuclear extract alone to the specific semiconservative DNA replication reaction. These results show that these in vitro systems closely resemble SV40 DNA replication in vivo and provide an assay that should be useful for the purification and subsequent characterization of viral and cellular proteins involved in DNA replication.     

Dimerization of simian virus 40 T-antigen hexamers activates T-antigen DNA helicase activity.

Chromosomal DNA replication in higher eukaryotes takes place in DNA synthesis factories containing numerous replication forks. We explored the role of replication fork aggregation in vitro, using as a model the simian virus 40 (SV40) large tumor antigen (T antigen), essential for its DNA helicase and origin-binding activities. Previous studies have shown that T antigen binds model DNA replication forks primarily as a hexamer (TAgH) and to a lesser extent as a double hexamer (TAgDH). We find that DNA unwinding in the presence of ATP or other nucleotides strongly correlates with the formation of TAgDH-DNA fork complexes. TAgH- and TAgDH-fork complexes were isolated, and the TAgDH-bound fork was denatured at a 15-fold-higher rate during the initial times of unwinding. TAgDH bound preferentially to a DNA substrate containing a 50-nucleotide bubble, indicating the bridging of each single-stranded DNA/duplex DNA junction, and this DNA molecule was also unwound at a high rate. Both the TAgH- and TAgDH-fork complexes were relatively stable, with the half-life of the TAgDH-fork complex greater than 40 min. Our data therefore indicate that the linking of two viral replication forks serves to activate DNA replication.     

Effects of biological DNA precursor pool asymmetry upon accuracy of DNA replication in vitro

Deoxyguanosine triphosphate is underrepresented among the four common deoxyribonucleoside triphosphates (dNTPs), typically accounting for just 5-10% of the total dNTP pool. We have asked whether this pool asymmetry affects the fidelity of DNA replication, by use of an in vitro assay in which an M13 phagemid containing the Escherichia coli lacZalpha gene and an SV40 replication origin is replicated by extracts of human cells. By monitoring reversion of either a TGA or TAA codon within the lacZalpha gene, we found that replication in "biologically biased" dNTPs, representing our estimate of the concentrations in HeLa cell nuclei, is not significantly more accurate than when measured in reaction mixtures containing the four dNTPs at equimolar concentrations. However, sequence analysis of revertants revealed significantly different patterns of mispairing events leading to mutation. During replication at biased dNTP levels, mutations at the site 5' to C in the template strand for the TGA triplet were less frequent than seen in equimolar reaction mixtures, suggesting that extension from mismatches at this site is relatively slow, and proofreading efficiency high, when dGTP is the next nucleotide to be incorporated. Mismatches opposite template C, which might have been favored by the low physiological concentrations of dGTP, were not favored in our in vitro system, although one particular substitution at this site, TGA-->TTA, was strongly favored at low [dGTP]. An excess of one dNTP was found in our system to be more mutagenic than a corresponding deficiency. We also estimated dNTP concentrations in non-transformed human fibroblasts and found that in vitro replication at these levels caused significantly fewer mutations than we observed under equimolar conditions (100 microM each dNTP). This increased replication fidelity may result from increased proofreading efficiency at the lower dNTP levels; however, replication rates were decreased only slightly at these non-transformed fibroblast concentrations.     

The ubiquitous potential Z-forming sequence of eucaryotes, (dT-dG)n . (dC-dA)n, is not detectable in the genomes of eubacteria, archaebacteria, or mitochondria.

The potential Z-forming sequence (dT-dG)n . (dC-dA)n is an abundant, interspersed repeat element that is ubiquitous in eucaryotic nuclear genomes. We report that in contrast to eucaryotic nuclear DNA, the genomes of eubacteria, archaebacteria, and mitochondria lack this sequence, since even a single tract of greater than or equal to 14 base pairs in length is not detectable through either hybridization or sequence analysis. Interestingly, the phylogenetic distribution of the (dT-dG)n . (dC-dA)n repeat exhibits a striking parallel to that of (dT-dC)n . (dG-dA)n, but not to other homocopolymeric sequences such as (dC-dG)n . (dC-dG)n or (dT-dA)n . (dT-dA)n.