DNA polymerase alpha from HeLa cells synthesizes DNA with high fidelity in a reconstituted replication system

To determine the contribution that DNA polymerase alpha makes to the overall DNA replication fidelity in mammalian systems, we measured the fidelity of replication of the SV40-based shuttle vector, pZ189, in a reconstituted in vitro DNA replication system which contained purified HeLa DNA polymerase alpha (in addition to single-stranded DNA binding protein, topoisomerase II, DNA ligase, 5'----3' exonuclease, ribonuclease H, and SV40 T-antigen). We found that DNA polymerase alpha is highly accurate when carrying out bidirectional replication in this system. This high fidelity of replication by DNA polymerase alpha in the reconstituted replication system contrasts with a relatively low fidelity of gap-filling DNA synthesis on the same target gene by purified HeLa cell DNA polymerase alpha in the absence of other replication factors. The fidelity of DNA replication by DNA polymerase alpha, although relatively high in the reconstituted system, is about 4-fold lower than DNA replication in a crude HeLa cell extract which contains additional replication factors including DNA polymerase delta. These results demonstrate that DNA polymerase alpha has the capacity to replicate DNA with high fidelity when carrying out semiconservative DNA replication in a minimal reconstituted replication system, but additional cellular factors not present in the reconstituted system may contribute to the higher replication fidelity of the crude system.     

Cellular factors required for papillomavirus DNA replication.

In vitro replication of papillomavirus DNA has been carried out with a combination of purified proteins and partially purified extracts made from human cells. DNA synthesis requires the viral E1 protein and the papillomavirus origin of replication. The E2 protein stimulates DNA synthesis in a binding site-independent manner. Papillomavirus DNA replication is also dependent on the cellular factors replication protein A, replication factor C, and proliferating-cell nuclear antigen as well as a phosphocellulose column fraction (IIA). Fraction IIA contains DNA polymerase alpha-primase and DNA polymerase delta. Both of these polymerases are essential for papillomavirus DNA replication in vitro. However, unlike the case with T-antigen-dependent replication from the simian virus 40 origin, purified DNA polymerase alpha-primase and delta cannot efficiently replace fraction IIA in the replication reaction. Hence, additional cellular factors seem to be required for papillomavirus DNA replication. Interestingly, replication factor C and proliferating-cell nuclear antigen are more stringently required for DNA synthesis in the papillomavirus system than in the simian virus 40 in vitro system. These distinctions indicate that there must be mechanistic differences between the DNA replication systems of papillomavirus and simian virus 40.     

Regulation of dna replication after heat shock by replication protein a-nucleolin interactions

Heat shock inhibits replicative DNA synthesis, but the underlying mechanism remains unknown. We investigated mechanistic aspects of this regulation in melanoma cells using a simian virus 40 (SV40)-based in vitro DNA replication assay. Heat shock (44 degrees C) caused a monotonic inhibition of cellular DNA replication following exposures for 5-90 min. SV40 DNA replication activity in extracts of similarly heated cells also decreased after 5-30 min of exposure, but returned to near control levels after 60-90 min of exposure. This transient inhibition of SV40 DNA replication was eliminated by recombinant replication protein A (rRPA), suggesting a regulatory process targeting this key DNA replication factor. SV40 DNA replication inhibition was associated with a transient increase in the interaction between nucleolin and RPA that peaked at 20-30 min. Because binding to nucleolin compromises the ability of RPA to support SV40 DNA replication, we suggest that the observed interaction reflects a mechanism whereby DNA replication is regulated after heat shock. The relevance of this interaction to the regulation of cellular DNA replication is indicated by the transient translocation in heated cells of nucleolin from the nucleolus into the nucleoplasm with kinetics very similar to those of SV40 DNA replication inhibition and of RPA-nucleolin interaction. Because the targeting of RPA by nucleolin in heated cells occurs in an environment that preserves the activity of several essential DNA replication factors, active processes may contribute to DNA replication inhibition to a larger degree than presently thought. RPA-nucleolin interactions may reflect an early step in the regulation of DNA replication, as nucleolin relocalized into the nucleolus 1-2 h after heat exposure but cellular DNA replication remained inhibited for up to 8 h. We propose that the nucleolus functions as a heat sensor that uses nucleolin as a signaling molecule to initiate inhibitory responses equivalent to a checkpoint.     

The eukaryotic replication complex and its affinity modification analysis

Replication of eukaryotic DNA is driven by a protein complex, in which the central part is played by DNA polymerases. Synthesis with eukaryotic DNA polymerases alpha, delta, and epsilon involves various replication factors, including the replication protein A, replication factor C, proliferating cell nuclear antigen, etc. Replication enzymes and factors also participate in DNA repair, which is in an interplay with DNA replication. The function of the entire multicomponent system is regulated by protein--nucleic acid and protein--protein interactions. The eukaryotic replication complex was not isolated as a stable supramolecular structure, suggesting its dynamic organization. Hence X-ray analysis and other instrumental techniques are hardly suitable for studying this system. An alternative approach is affinity modification. Its most promising version involves in situ generation of photoreactive DNA replication intermediates. The review considers the recent progress in photoaffinity modification studies of DNA polymerases, eukaryotic replication factors, and their interactions with DNA replication intermediates.     

Intracellular Replication of Mycoplasmavirus MVL51

The intracellular replication of MVL51, a group L1 mycoplasmavirus, was investigated. The single-stranded parental DNA was found to enter the cell and become converted to double-stranded DNA. This replicated to yield additional double-stranded DNA molecules. The parental viral DNA was found to leave the replication complex and become associated with large molecular weight DNA not involved with viral replication. Progeny viral DNA formed from the double-stranded DNA and an intracellular accumulation of virus chromosome size DNA was observed. The interpretation of this data and a suggested model for the viral replication are discussed and compared to viral DNA replication models for other single-stranded DNA viruses.     

MicroRNA-regulated stress response in cancer and its clinical implications

The precise coordination of the different steps of DNA replication is critical for the maintenance of genome stability. We have probed the mechanisms coupling various components of the replication machinery and their response to polymerase stalling by inhibition of the DNA polymerases in living mammalian cells with aphidicolin. We observed little change in the behaviour of proteins involved in the initiation of DNA replication. In contrast, we detected a marked accumulation of the single stranded DNA binding factor RPA34 at sites of DNA replication. Finally, we demonstrate that proteins involved in the elongation step of DNA synthesis dissociate from replication foci in the presence of aphidicolin. Taken together, these data indicate that inhibition of processive DNA polymerases uncouples the initiation of DNA replication from subsequent elongation steps. We, therefore, propose that the replication machinery is made up of distinct functional sub-modules that allow a flexible and dynamic response to challenges during DNA replication.     

Regulation of DNA replication during development

As development unfolds, DNA replication is not only coordinated with cell proliferation, but is regulated uniquely in specific cell types and organs. This differential regulation of DNA synthesis requires crosstalk between DNA replication and differentiation. This dynamic aspect of DNA replication is highlighted by the finding that the distribution of replication origins varies between differentiated cell types and changes with differentiation. Moreover, differential DNA replication in some cell types can lead to increases or decreases in gene copy number along chromosomes. This review highlights the recent advances and technologies that have provided us with new insights into the developmental regulation of DNA replication.     

Molecular Weight of Deoxyribonucleic Acid Synthesized During Initiation of Chromosome Replication in Escherichia coli

Alkaline sucrose gradients were used to study the molecular weight of deoxyribonucleic acid (DNA) synthesized during the initiation of chromosome replication in Escherichia coli 15 TAU-bar. The experiments were conducted to determine whether newly synthesized, replication origin DNA is attached to higher-molecular-weight parental DNA. Little of the DNA synthesized after readdition of required amino acids to cells previously deprived of the amino acids was present in DNA with a molecular weight comparable to that of the parental DNA. The newly synthesized, low-molecular-weight DNA rapidly appeared in higher-molecular-weight material, but there was an upper limit to the size of this intermediate-molecular-weight DNA. This limit was not observed when exponentially growing cells converted newly synthesized DNA to higher-molecular-weight material. The size of the intermediate-molecular-weight DNA was related to the age of the replication forks, and the size increased as the replication forks moved further from the replication origin. The results indicate that the newly synthesized replication origin DNA is not attached to parental DNA, but it is rapidly attached to the growing strands that extend from the replication fork to the replication origin, or to the other replication fork if replication is bidirectional. Experiments are reported which demonstrate that the DNA investigated was from the vicinity of the replication origin and was not plasmid DNA or DNA from random positions on the chromosome.     

Deoxyribonucleic Acid-Deoxyribonucleic Acid Hybridization Assay for Replication Origin Deoxyribonucleic Acid of Escherichia coli

Deoxyribonucleic acid (DNA)-DNA hybridization on nitrocellulose filters can be used to assay for replication origin DNA from Escherichia coli if the DNA attached to the filters is enriched for the replication origin sequences. Such DNA can be readily isolated from very rapidly growing cells. When low amounts of this DNA were attached to filters, radioactively labeled DNA from the replication origin hybridized 1.7 times as well as radioactive replication terminus DNA. Under identical conditions, radioactively labeled DNA from exponentially growing cells hybridized only 1.3 times as well as radioactive replication terminus DNA. The replication origin, replication terminus, and randomly labeled DNA hybridized with similar efficiencies to filters containing DNA isolated from cells incubated in the absence of required amino acids. This DNA appeared to have all sequences present at equal frequencies. The hybridization assay was used to demonstrate that the DNA synthesized shortly after the addition of amino acids to cells previously deprived of required amino acids was primarily from the replication origin and then rapidly became similar to DNA synthesized by exponentially growing cells.     

Compartmentalization of prokaryotic DNA replication

It becomes now apparent that prokaryotic DNA replication takes place at specific intracellular locations. Early studies indicated that chromosomal DNA replication, as well as plasmid and viral DNA replication, occurs in close association with the bacterial membrane. Moreover, over the last several years, it has been shown that some replication proteins and specific DNA sequences are localized to particular subcellular regions in bacteria, supporting the existence of replication compartments. Although the mechanisms underlying compartmentalization of prokaryotic DNA replication are largely unknown, the docking of replication factors to large organizing structures may be important for the assembly of active replication complexes. In this article, we review the current state of this subject in two bacterial species, Escherichia coli and Bacillus subtilis, focusing our attention in both chromosomal and extrachromosomal DNA replication. A comparison with eukaryotic systems is also presented.     

Characterization of functional domains in human Claspin

Claspin is a mediator of the ATR-dependent DNA replication checkpoint in human cells and also promotes DNA replication fork progression and stability. Though Claspin has been shown to bind DNA and co-immunoprecipitate with other replication fork-associated proteins, the specific protein-protein and protein-DNA interactions that are important for Claspin function are not known. We therefore purified several domains of human Claspin and then tested for direct interactions of these fragments with several replication fork-associated proteins and with DNA. Our data show that the N terminus of Claspin binds to the replicative helicase co-factor Cdc45, the Timeless protein and a branched, replication fork-like DNA structure. In contrast, the C terminus of Claspin associates with DNA polymerase epsilon and Rad17-Replication Factor C (RFC). We conclude that multiple protein-DNA and protein-protein interactions may be important for Claspin function during DNA replication and DNA replication checkpoint signaling.Key words: Claspin, DNA replication, checkpoint, DNA damage, Cdc45, DNA polymerase, Rad17     

Induction of DNA replication-mediated double strand breaks by psoralen DNA interstrand cross-links

The effect of DNA interstrand cross-links (cross-links) on DNA replication was examined with a cell-free SV40 origin-dependent DNA replication system. A defined template DNA with a single psoralen cross-link and the SV40 origin of replication was replicated by HeLa cell-free extract in the presence of SV40 large T antigen. The psoralen cross-link inhibited DNA replication by terminating chain elongation at 1-50 nucleotides before the cross-linked sites. The termination of DNA replication by the cross-links mediated the generation of double strand breaks near the cross-linked sites. These results are the first biochemical evidence of the generation of double strand breaks by DNA replication.     

Depletion of cellular pre-replication complex factors results in increased human cytomegalovirus DNA replication

Although HCMV encodes many genes required for the replication of its DNA genome, no HCMV-encoded orthologue of the origin binding protein, which has been identified in other herpesviruses, has been identified. This has led to speculation that HCMV may use other viral proteins or possibly cellular factors for the initiation of DNA synthesis. It is also unclear whether cellular replication factors are required for efficient replication of viral DNA during or after viral replication origin recognition. Consequently, we have asked whether cellular pre-replication (pre-RC) factors that are either initially associated with cellular origin of replication (e.g. ORC2), those which recruit other replication factors (e.g. Cdt1 or Cdc6) or those which are subsequently recruited (e.g. MCMs) play any role in the HCMV DNA replication. We show that whilst RNAi-mediated knock-down of these factors in the cell affects cellular DNA replication, as predicted, it results in concomitant increases in viral DNA replication. These data show that cellular factors which initiate cellular DNA synthesis are not required for the initiation of replication of viral DNA and suggest that inhibition of cellular DNA synthesis, in itself, fosters conditions which are conducive to viral DNA replication.     

PriC-mediated DNA Replication Restart Requires PriC Complex Formation with the Single-stranded DNA-binding Protein

Frequent collisions between cellular DNA replication complexes (replisomes) and obstacles such as damaged DNA or frozen protein complexes make DNA replication fork progression surprisingly sporadic. These collisions can lead to the ejection of replisomes prior to completion of replication, which, if left unrepaired, results in bacterial cell death. As such, bacteria have evolved DNA replication restart mechanisms that function to reload replisomes onto abandoned DNA replication forks. Here, we define a direct interaction between PriC, a key Escherichia coli DNA replication restart protein, and the single-stranded DNA-binding protein (SSB), a protein that is ubiquitously associated with DNA replication forks. PriC/SSB complex formation requires evolutionarily conserved residues from both proteins, including a pair of Arg residues from PriC and the C terminus of SSB. In vitro, disruption of the PriC/SSB interface by sequence changes in either protein blocks the first step of DNA replication restart, reloading of the replicative DnaB helicase onto an abandoned replication fork. Consistent with the critical role of PriC/SSB complex formation in DNA replication restart, PriC variants that cannot bind SSB are non-functional in vivo. Single-molecule experiments demonstrate that PriC binding to SSB alters SSB/DNA complexes, exposing single-stranded DNA and creating a platform for other proteins to bind. These data lead to a model in which PriC interaction with SSB remodels SSB/DNA structures at abandoned DNA replication forks to create a DNA structure that is competent for DnaB loading.     

Mammalian DNA polymerase alpha: a replication-competent holoenzyme form from calf thymus

Calf thymus DNA polymerase alpha, like the replication-specific DNA polymerase III holoenzyme of Escherichia coli, can be isolated as a distinct complex. A specific multiprotein form of the polymerase alpha, a form designated replication-competent (RC) holoenzyme, consists of a complex of a polymerase-primase core and at least six other polypeptides. The RC holoenzyme can efficiently replicate several naturally occurring templates, including the genomic DNA of the porcine circovirus (PCV). The DNA of this virion consists of a single-stranded circle with a defined replication origin, and its replication requires the cellular DNA replication machinery. It might therefore provide an invaluable opportunity to investigate chromosomal replication mechanisms, analogous to the way that studies on E. coli bacteriophage DNA replication elucidated host DNA replication mechanisms. Calf RC holoenzyme alpha selectively initiates PCV DNA replication in vitro at a site that possibly represents a consensus sequence of cellular DNA replication origins. The cell-free PCV replication system will be exploited for the in vitro dissection and reconstitution of the RC holoenzyme and the functional analysis of its component polypeptides.     

Discontinuous or semi‐discontinuous DNA replication in Escherichia coli?

The postulate that a stalled/collapsed replication fork will be generated when the replication complex encounters a UV-induced lesion in the template for leading-strand DNA synthesis is based on the model of semi-discontinuous DNA replication. A review of existing data indicates that the semi-discontinuous DNA replication model is supported by data from in vitro studies, while the discontinuous DNA replication model is supported by in vivo studies in Escherichia coli. Until the question of whether DNA replicates discontinuously in one or both strands is clearly resolved, any model building based on either one of the two DNA replication models should be treated with caution.     

HUWE1 interacts with PCNA to alleviate replication stress

Defects in DNA replication, DNA damage response, and DNA repair compromise genomic stability and promote cancer development. In particular, unrepaired DNA lesions can arrest the progression of the DNA replication machinery during S‐phase, causing replication stress, mutations, and DNA breaks. HUWE1 is a HECT‐type ubiquitin ligase that targets proteins involved in cell fate, survival, and differentiation. Here, we report that HUWE1 is essential for genomic stability, by promoting replication of damaged DNA. We show that HUWE1‐knockout cells are unable to mitigate replication stress, resulting in replication defects and DNA breakage. Importantly, we find that this novel role of HUWE1 requires its interaction with the replication factor PCNA, a master regulator of replication fork restart, at stalled replication forks. Finally, we provide evidence that HUWE1 mono‐ubiquitinates H2AX to promote signaling at stalled forks. Altogether, our work identifies HUWE1 as a novel regulator of the replication stress response.     

Dideoxynucleoside triphosphates inhibit a late stage of SV40 DNA replicationin vitro

Summary The role of DNA polymerases in the replication of SV40 DNA was studied using a T-antigen-dependent assay supplemented with a human KB cell extract. Inhibition of DNA polymerase α by addition of aphidicolin or monoclonal antibodies prevented DNA synthesis, confirming the requirement for this enzyme in replication. The replication process was unaffected by ddTTP at a concentration (5 μM) inhibitory to DNA polymerases β and γ, however, higher concentrations of ddTTP (200 μM) caused an apparent accumulation of relaxed circular plasmid with a concomitant decrease in DNA synthesis. An analysis of this replication intermediate indicated that it was formed during the replication reaction and that the replicative cycle was nearly complete. A kinetic study of ddTTP inhibition strongly suggested DNA polymerase ε (PCNA-independent DNA polymerase δ) was the target of the inhibitor and that this enzyme functions during the final stages of DNA replication.     

Bizelesin, a bifunctional cyclopropylpyrroloindole alkylating agent, inhibits simian virus 40 replication in trans by induction of an inhibitor.

Bizelesin, a bifunctional DNA minor groove alkylating agent, inhibits both cellular and viral (SV40) DNA replication in whole cells. Bizelesin inhibition of SV40 DNA replication was analyzed in SV40-infected cells, using two-dimensional (2D) neutral agarose gel electrophoresis, and in a cell-free SV40 DNA replication assay. Within 1 h of bizelesin addition to infected cells, a similar rapid decrease in both the level of SV40 replication intermediates and replication activity was observed, indicating inhibition of initiation of SV40 DNA replication. However, prolonged bizelesin treatment (>/=2 h) was associated with a reduced extent of elongation of SV40 replicons, as well as the appearance on 2D gels of intense spots, suggestive of replication pause sites. Inhibition of elongation and induction of replication pause sites may result from the formation of bizelesin covalent bonds on replicating SV40 molecules. The level of in vitro replication of SV40 DNA also was reduced when extracts from bizelesin-treated HeLa cells were used. This effect was not dependent upon the formation of bizelesin covalent bonds with the template DNA. Mixing experiments, using extracts from control and bizelesin-treated cells, indicated that reduced DNA replication competence was due to the presence of a trans-acting DNA replication inhibitor, rather than to decreased levels or inactivation of essential replication factor(s).