Clusters,factories and domains

During S-phase of the cell cycle, chromosomal DNA is replicated according to a complex replication timing program, with megabase-sized domains replicating at different times. DNA fibre analysis reveals that clusters of adjacent replication origins fire near-synchronously. Analysis of replicating cells by light microscopy shows that DNA synthesis occurs in discrete foci or factories. The relationship between timing domains, origin clusters and replication foci is currently unclear. Recent work, using a hybrid Xenopus/hamster replication system, has shown that when CDK levels are manipulated during S-phase the activation of replication factories can be uncoupled from progression through the replication timing program. Here, we use data from this hybrid system to investigate potential relationships between timing domains, origin clusters and replication foci. We suggest that each timing domain typically comprises several replicon clusters, which are usually processed sequentially by replication factories. We discuss how replication might be regulated at different levels to create this complex organisation and the potential involvement of CDKs in this process.     

Mapping of a Physarum chromosomal origin of replication tightly linked to a developmentally-regulated profilin gene.

We compared the pattern of replication of two cell-type specific profilin genes in one developmental stage of the slime mold Physarum polycephalum. Taking advantage of the natural synchrony of S-phase within the plasmodium, we established that the actively transcribed profilin P gene is tightly linked to a chromosomal replication origin and is replicated at the onset of S-phase. In contrast, the inactive profilin A gene is not associated with a replication origin and it is duplicated in mid S-phase. Mapping by two-dimensional gel electrophoresis defines a short DNA fragment in the proximal upstream region of the profilin P gene from which bidirectional replication is initiated. We further provide an estimate of the kinetics of elongation of the replicon and demonstrate that the 2 alleles of the profilin P gene are coordinately replicated. All these results were obtained on total DNA preparations extracted from untreated cells. They provide a strong evidence for site specific initiation of DNA replication in Physarum.     

Nek1 interacts with Ku80 to assist chromatin loading of replication factors and S-phase progression

NIMA-related kinases (Neks) play divergent roles in mammalian cells. While several Neks regulate mitosis, Nek1 was reported to regulate DNA damage response, centrosome duplication and primary cilium formation. Whether Nek1 participates in cell cycle regulation is not known. Here we report that loss of Nek1 results in severe proliferation defect due to a delay in S-phase of the cell cycle. Nek1-deficient cells show replication stress and checkpoint activation under normal growth conditions. Nek1 accumulates on the chromatin during normal DNA replication. In response to replication stress, Nek1 is further activated for chromatin localization. Nek1 interacts with Ku80 and, in Nek1-deficient cells chromatin localization of Ku80 and several other DNA replication factors is significantly reduced. Thus, Nek1 may facilitate S-phase progression by interacting with Ku80 and regulating chromatin loading of replication factors.     

Chorion gene amplification in Drosophila: A model for metazoan origins of DNA replication and S-phase control.

The mechanisms controlling duplication of the metazoan genome are only beginning to be understood. It is still unclear what organization of DNA sequences constitutes a chromosomal origin of DNA replication, and the regulation of origin activity during the cell cycle has not been fully revealed. We review recent results that indicate that chorion gene amplification in follicle cells of the Drosophila ovary is a model for investigating metazoan replication. Evaluation of cis sequence organization and function suggests that chorion loci share attributes with other replicons and provides insights into metazoan origin structure. Moreover, recent results indicate that chorion origins respond to S-phase control, but escape mechanisms that inhibit other origins from firing more than once in a cell cycle. Several identified genes that mediate amplification are critical for the cell cycle control of replication initiation. It is likely that further genetic screens for mutations that disrupt amplification will identify the cadre of proteins associated with origins and the regulatory pathways that control their activity. Furthermore, the recent development of methods to detect amplification in situ has uncovered new aspects of its developmental control. Examining this control will reveal links between developmental pathways and the cell cycle machinery. Visualization of amplifying chorion genes with high resolution also represents an opportunity to evaluate the influence of nuclear and chromosome structure on origin activity. The study of chorion amplification in Drosophila, therefore, provides great potential for the genetic and molecular dissection of metazoan replication.     

Defining the replication program through the chromatin landscape

DNA replication is an essential cell cycle event required for the accurate and timely duplication of the chromosomes. It is essential that the genome is replicated accurately and completely within the confines of S-phase. Failure to completely copy the genome has the potential to result in catastrophic genomic instability. Replication initiates in a coordinated manner from multiple locations, termed origins of replication, distributed across each of the chromosomes. The selection of these origins of replication is a dynamic process responding to both developmental and tissue-specific signals. In this review, we explore the role of the local chromatin environment in regulating the DNA replication program at the level of origin selection and activation. Finally, there is increasing molecular evidence that the DNA replication program itself affects the chromatin landscape, suggesting that DNA replication is critical for both genetic and epigenetic inheritance.     

Inhibition of S-phase progression triggered by UVA-induced ROS does not require a functional DNA damage checkpoint response in mammalian cells

Ultraviolet A (UVA) radiation represents more than 90% of the UV spectrum reaching Earth's surface. Exposure to UV light, especially the UVA part, induces the formation of photoexcited states of cellular photosensitizers with subsequent generation of reactive oxygen species (ROS) leading to damages to membrane lipids, proteins and nucleic acids. Although UVA, unlike UVC and UVB, is poorly absorbed by DNA, it inhibits cell cycle progression, especially during S-phase. In the present study, we examined the role of the DNA damage checkpoint response in UVA-induced inhibition of DNA replication. We provide evidence that UVA delays S-phase in a dose dependent manner and that UVA-irradiated S-phase cells accumulate in G2/M. We show that upon UVA irradiation ATM-, ATR- and p38-dependent signalling pathways are activated, and that Chk1 phosphorylation is ATR/Hus1 dependent while Chk2 phosphorylation is ATM dependent. To assess for a role of these pathways in UVA-induced inhibition of DNA replication, we investigated (i) cell cycle progression of BrdU labelled S-phase cells by flow cytometry and (ii) incorporation of [methyl-(3)H]thymidine, as a marker of DNA replication, in ATM, ATR and p38 proficient and deficient cells. We demonstrate that none of these pathways is required to delay DNA replication in response to UVA, thus ruling out a role of the canonical S-phase checkpoint response in this process. On the contrary, scavenging of UVA-induced reactive oxygen species (ROS) by the antioxidant N-acetyl-l-cystein or depletion of vitamins during UVA exposure significantly restores DNA synthesis. We propose that inhibition of DNA replication is due to impaired replication fork progression, rather as a consequence of UVA-induced oxidative damage to protein than to DNA.     

Replication fork dynamics and the DNA damage response

Prevention and repair of DNA damage is essential for maintenance of genomic stability and cell survival. DNA replication during S-phase can be a source of DNA damage if endogenous or exogenous stresses impair the progression of replication forks. It has become increasingly clear that DNA-damage-response pathways do not only respond to the presence of damaged DNA, but also modulate DNA replication dynamics to prevent DNA damage formation during S-phase. Such observations may help explain the developmental defects or cancer predisposition caused by mutations in DNA-damage-response genes. The present review focuses on molecular mechanisms by which DNA-damage-response pathways control and promote replication dynamics in vertebrate cells. In particular, DNA damage pathways contribute to proper replication by regulating replication initiation, stabilizing transiently stalled forks, promoting replication restart and facilitating fork movement on difficult-to-replicate templates. If replication fork progression fails to be rescued, this may lead to DNA damage and genomic instability via nuclease processing of aberrant fork structures or incomplete sister chromatid separation during mitosis.     

Centrosome duplication proceeds during mimosine-induced G1 cell cycle arrest

Centrosome duplication must remain coordinated with cell cycle progression to ensure the formation of a strictly bipolar mitotic spindle, but the mechanisms that regulate this coordination are poorly understood. Previous work has shown that prolonged S-phase is permissive for centrosome duplication, but prolonging either G2 or M-phase cannot support duplication. To examine whether G1 is permissive for centrosome duplication, we release serum-starved G0 cells into mimosine, which delays the cell cycle in G1. We find that in mimosine, centrosome duplication does occur, albeit slowly compared with cells that progress into S-phase; centrosome duplication in mimosine-treated cells also proceeds in the absence of a rise in Cdk2 kinase activity normally associated with the G1/S transition. CHO cells arrested with mimosine can also assemble more than four centrioles (termed "centrosome amplification"), but the extent of centrosome amplification during prolonged G1 is decreased compared to cells that enter S-phase and activate the Cdk2-cyclin complex. Together, our results suggest a model, which predicts that entry into S-phase and the rise in Cdk2 activity associated with this transition are not absolutely required to initiate centrosome duplication, but rather, serve to entrain the centrosome reproduction cycle with cell cycle progression.     

Recovery from effects of heat on DNA synthesis in Chinese hamster ovary cells

The hyperthermic inhibition of cellular DNA synthesis, i.e., reduction in replicon initiation and delay in DNA chain elongation, was previously postulated to be involved in the induction of chromosomal aberrations believed to be largely responsible for killing S-phase cells. Utilizing asynchronous Chinese hamster ovary cells heated for 15 min at 45.5 degrees C, an increase in single-stranded regions in replicating DNA (as measured by BND-cellulose chromatography) persisted in heated cells for as long as replicon initiation was affected. Alkaline sucrose gradient analyses of cells pulse-labeled immediately after heating with [3H]thymidine and subsequently chased at 37 degrees C revealed that these S-phase cells can eventually complete elongation of the replicons in operation at the time of heating, but required about six times as long relative to control cells which completed replicon elongation within 4 h. DNA chain elongation into multicluster-sized molecules was prevented for up to 18 h in these heated cells, resulting in a buildup of cluster-sized molecules (approximately 120-160 S) mainly because of the long-term heat damage to the replicon initiation process. Utilizing bromodeoxyuridine (BrdU)-propidium iodide bivariate analysis on a flow cytometer to measure cell progression, control cells pulsed with BrdU and chased in unlabeled medium progressed through S and G2M with cell division starting after 2 h of chase time. In contrast, the majority of the heated S-phase cells progressed slowly and remained blocked in S phase for about 18 h before cell division was observed after 24 h postheat. Our findings suggest that possible sites for where the chromosomal aberrations may be occurring in heated S-phase cells are either (1) at the persistent single-stranded DNA regions or (2) at the regions between clusters of replicons, because this long-term heat damage to the DNA replication process might lead to many opportunities for abnormal DNA and/or protein exchanges to occur at these two sites.     

Cdc45 limits replicon usage from a low density of preRCs in mammalian cells

Little is known about mammalian preRC stoichiometry, the number of preRCs on chromosomes, and how this relates to replicon size and usage. We show here that, on average, each 100-kb of the mammalian genome contains a preRC composed of approximately one ORC hexamer, 4-5 MCM hexamers, and 2 Cdc6. Relative to these subunits, ～0.35 total molecules of the pre-Initiation Complex factor Cdc45 are present. Thus, based on ORC availability, somatic cells contain ～70,000 preRCs of this average total stoichiometry, although subunits may not be juxtaposed with each other. Except for ORC, the chromatin-bound complement of preRC subunits is even lower. Cdc45 is present at very low levels relative to the preRC subunits, but is highly stable, and the same limited number of stable Cdc45 molecules are present from the beginning of S-phase to its completion. Efforts to artificially increase Cdc45 levels through ectopic expression block cell growth. However, microinjection of excess purified Cdc45 into S-phase nuclei activates additional replication foci by three-fold, indicating that Cdc45 functions to activate dormant preRCs and is rate-limiting for somatic replicon usage. Paradoxically, although Cdc45 colocalizes in vivo with some MCM sites and is rate-limiting for DNA replication to occur, neither Cdc45 nor MCMs colocalize with active replication sites. Embryonic metazoan chromatin consists of small replicons that are used efficiently via an excess of preRC subunits. In contrast, somatic mammalian cells contain a low density of preRCs, each containing only a few MCMs that compete for limiting amounts of Cdc45. This provides a molecular explanation why, relative to embryonic replicon dynamics, somatic replicons are, on average, larger and origin efficiency tends to be lower. The stable, continuous, and rate-limiting nature of Cdc45 suggests that Cdc45 contributes to the staggering of replicon usage throughout S-phase, and that replicon activation requires reutilization of existing Cdc45 during S-phase.     

Physical relationship between a gene and its origin of replication in Physarum polycephalum

Taking advantage of the natural synchrony of the S-phase within the plasmodium of Physarum polycephalum, we extracted highly synchronous DNA samples at precise time points in early S-phase. We then separated, by electrophoresis under denaturating conditions, the newly synthesized DNA strands of the nascent chromosomal replicons from the parental DNA template. Using the cDNA clone of the early-replicating LAV1-2 gene as a probe, we could establish by filter hybridization that the elongation rate of the replicon which encompasses this gene is constant, at a rate of 1 kb/min during the first 30 min of S-phase. The smallest replication intermediate (RI) that we have detected by probing with the LAV1-2 cDNA was 5 kb long, suggesting that the LAV1-2 gene and its origin of replication are closely associated within the chromosome. This procedure should facilitate the mapping of replication origins within the genome of Physarum.     

The histone methyltransferase SET8 is required for S-phase progression

Chromatin structure and function is influenced by histone posttranslational modifications. SET8 (also known as PR-Set7 and SETD8) is a histone methyltransferase that monomethylates histonfe H4-K20. However, a function for SET8 in mammalian cell proliferation has not been determined. We show that small interfering RNA inhibition of SET8 expression leads to decreased cell proliferation and accumulation of cells in S phase. This is accompanied by DNA double-strand break (DSB) induction and recruitment of the DNA repair proteins replication protein A, Rad51, and 53BP1 to damaged regions. SET8 depletion causes DNA damage specifically during replication, which induces a Chk1-mediated S-phase checkpoint. Furthermore, we find that SET8 interacts with proliferating cell nuclear antigen through a conserved motif, and SET8 is required for DNA replication fork progression. Finally, codepletion of Rad51, an important homologous recombination repair protein, abrogates the DNA damage after SET8 depletion. Overall, we show that SET8 is essential for genomic stability in mammalian cells and that decreased expression of SET8 results in DNA damage and Chk1-dependent S-phase arrest.     

Delaying S-phase progression rescues cells from heat-induced S-phase hypertoxicity

The mechanism by which a cell protects itself from the lethal effects of heat shock and other stress-inducing agents is the subject of much research. We have investigated the relationship between heat-induced damage to DNA replication machinery and the lethal effects of heat shock, in S-phase cells, which are more sensitive to heat shock than either G1 or G2. We found that maintaining cells in aphidicolin, which prevents the passage of cells through S-phase, can rescue S-phase HeLa cells from the lethal effects of heat shock. When S-phase, HeLa cells were held for 5-6 h in 3 microM aphidicolin the measured clonogenic survival was similar to that for exponentially growing cells. It is known, that heat shock induces denaturation or unfolding of proteins, rendering them less soluble and more likely to co-isolate with the nuclear matrix. Here, we show that enhanced binding of proteins involved in DNA replication (PCNA, RPA, and cyclin A), with the nuclear matrix, correlates with lethality of S-phase cells following heat shock under four different experimental conditions. Specifically, the amounts of RPA, PCNA, and cyclin A associated with the nuclear matrix when cells resumed progression through S-phase correlated with cell killing. Heat-induced enhanced binding of nuclear proteins involved with other aspects of DNA metabolism, (Mrell, PDI), do not show this correlation. These results support the hypothesis that heat-induced changes in the binding of proteins associated with DNA replication factories are the potentially lethal lesions, which become fixed to lethal lesions by S-phase progression but are repairable if S-phase progression is delayed.     

Highly mutagenic and severely imbalanced dNTP pools can escape detection by the S-phase checkpoint

A balanced supply of deoxyribonucleoside triphosphates (dNTPs) is one of the key prerequisites for faithful genome duplication. Both the overall concentration and the balance among the individual dNTPs (dATP, dTTP, dGTP, and dCTP) are tightly regulated, primarily by the enzyme ribonucleotide reductase (RNR). We asked whether dNTP pool imbalances interfere with cell cycle progression and are detected by the S-phase checkpoint, a genome surveillance mechanism activated in response to DNA damage or replication blocks. By introducing single amino acid substitutions in loop 2 of the allosteric specificity site of Saccharomyces cerevisiae RNR, we obtained a collection of strains with various dNTP pool imbalances. Even mild dNTP pool imbalances were mutagenic, but the mutagenic potential of different dNTP pool imbalances did not directly correlate with their severity. The S-phase checkpoint was activated by the depletion of one or several dNTPs. In contrast, when none of the dNTPs was limiting for DNA replication, even extreme and mutagenic dNTP pool imbalances did not activate the S-phase checkpoint and did not interfere with the cell cycle progression.     

Plk1 phosphorylation of Orc2 promotes DNA replication under conditions of stress

Polo-like kinase 1 (Plk1) plays pivotal roles in mitosis; however, little is known about its function in S phase. In this study, we show that inhibition of Plk1 impairs DNA replication and results in slow S-phase progression in cultured cancer cells. We have identified origin recognition complex 2 (Orc2), a member of the DNA replication machinery, as a Plk1 substrate and have shown that Plk1 phosphorylates Orc2 at Ser188 in vitro and in vivo. Furthermore, Orc2-S188 phosphorylation is enhanced when DNA replication is under challenge induced by ultraviolet, hydroxyurea, gemcitabine, or aphidicolin treatment. Cells expressing the unphosphorylatable mutant (S188A) of Orc2 had defects in DNA synthesis under stress, suggesting that this phosphorylation event is critical to maintain DNA replication under stress. To dissect the mechanism pertinent to this observation, we showed that Orc2-S188 phosphorylation associates with DNA replication origin and that cells expressing Orc2-S188A mutant fail to maintain the functional pre-replicative complex (pre-RC) under DNA replication stress. Furthermore, the intra-S-phase checkpoint is activated in Orc2-S188A-expressing cells to cause delay of S-phase progress. Our study suggests a novel role of Plk1 in facilitating DNA replication under conditions of stress to maintain genomic integrity.     

Cloning, sequencing, and functional analysis of a Marek''s disease virus origin of DNA replication.

Previously, we isolated a replicon from a defective Marek's disease virus (MDV), analogous to defective herpes simplex viruses (amplicons). Defective viruses contain cis-acting elements required for DNA synthesis and virus propagation such as an origin of DNA replication and a packaging-cleavage signal site. In this report, the MDV replicon was utilized to locate an origin of MDV DNA replication. A comparison of MDV replicon sequences with other herpesvirus replication origin sequences revealed a 90-bp sequence containing 72% identity to the lytic origin (oris) of herpes simplex virus type 1. This 90-bp sequence displayed no similarity to betaherpesvirus or gammaherpesvirus replication origins. The 90-bp sequence is arranged as an imperfect palindrome centered around an A+T-rich region. This sequence also contains a 9-bp motif (5'CGTTCGCAC3') highly conserved in alphaherpesvirus replication origins. To test functionality of the 90-bp putative MDV replication origin, we conducted DpnI replication assays with subclones generated from the 4-kbp MDV replicon. A 700-bp MDV replicon subfragment containing the 90-bp putative MDV replication origin sequence is capable of replicating in chicken embryo fibroblast cells cotransfected with helper virus DNA. In conclusion, we identified a functional origin of DNA replication in MDV. Similarity of MDV origin sequences to those of alphaherpesviruses supports the current contention that MDV is more closely related to alphaherpesviruses than to gammaherpesviruses.     

Retinoblastoma tumor suppressor protein signals through inhibition of cyclin-dependent kinase 2 activity to disrupt PCNA function in S phase

The retinoblastoma tumor suppressor protein (RB) is a negative regulator of the cell cycle that inhibits both G(1) and S-phase progression. While RB-mediated G(1) inhibition has been extensively studied, the mechanism utilized for S-phase inhibition is unknown. To delineate the mechanism through which RB inhibits DNA replication, we generated cells which inducibly express a constitutively active allele of RB (PSM-RB). We show that RB-mediated S-phase inhibition does not inhibit the chromatin binding function of MCM2 or RPA, suggesting that RB does not regulate the prereplication complex or disrupt early initiation events. However, activation of RB in S-phase cells disrupts the chromatin tethering of PCNA, a requisite component of the DNA replication machinery. The action of RB was S phase specific and did not inhibit the DNA damage-mediated association of PCNA with chromatin. We also show that RB-mediated PCNA inhibition was dependent on downregulation of CDK2 activity, which was achieved through the downregulation of cyclin A. Importantly, restoration of cyclin-dependent kinase 2 (CDK2)-cyclin A and thus PCNA activity partially restored S-phase progression in the presence of active RB. Therefore, the data presented identify RB-mediated regulation of PCNA activity via CDK2 attenuation as a mechanism through which RB regulates S-phase progression. Together, these findings identify a novel pathway of RB-mediated replication inhibition.