Cytometric analysis of DNA replication inhibited by emetine and cyclosporin A

DNA staining methods based on aspecific interactions with dye molecules have been replaced by an immunofluorescent approach to measure DNA replication. Biotin-11-dUTP was incorporated into permeable thymocytes isolated after emetine or cyclosporin A treatment of mice. Active sites of DNA replication were amplified based on biotin-avidin interaction and verified under fluorescent microscope. Cytometry of fluorescent images allow the direct measurement of replicating DNA without aspecific detection of total cellular DNA. Cytometric analysis of replication revealed that emetine acts at the early S phase, while cyclosporin A blocks in vivo DNA synthesis at mid S phase.     

Emetine allows identification of origins of mammalian DNA replication by imbalanced DNA synthesis, not through conservative nucleosome segregation.

In the presence of emetine, an inhibitor of protein synthesis, nascent DNA on forward arms of replication forks in hamster cell lines containing either single or amplified copies of the DHFR gene region was enriched 5- to 7-fold over nascent DNA on retrograde arms. This forward arm bias was observed on both sides of the specific origin of bidirectional DNA replication located 17 kb downstream of the hamster DHFR gene (OBR-1), consistent with at least 85% of replication forks within this region emanating from OBR-1. However, the replication fork asymmetry induced by emetine does not result from conservative nucleosome segregation, as previously believed, but from preferentially inhibiting Okazaki fragment synthesis on retrograde arms of forks to produce 'imbalanced DNA synthesis'. Three lines of evidence support this conclusion. First, the bias existed in long nascent DNA strands prior to nuclease digestion of non-nucleosomal DNA. Second, the fraction of RNA-primed Okazaki fragments was rapidly diminished. Third, electron microscopic analysis of SV40 DNA replicating in the presence of emetine revealed forks with single-stranded DNA on one arm, and nucleosomes randomly distributed to both arms. Thus, as with cycloheximide, nucleosome segregation in the presence of emetine was distributive.     

Cdk2 Activity Is Dispensable for the Onset of DNA Replication during the First Mitotic Cycles of the Sea Urchin Early Embryo

Earlier work reported the important role of Cdk2 as a regulator of DNA replication in somatic cells and inXenopusextracts. In the present report we analyzein vivothe involvement of Cdk2 in DNA replication during early embryogenesis using the first mitotic cycles of sea urchin embryos. UnfertilizedSphaerechinus granulariseggs are arrested after the second meiotic cytokinesis. Fertilization resumes the block and induces DNA replication after a short lag period, making sea urchin early embryo a good model for studyingin vivothe onset of DNA replication. We show that Cdk2 as well as its potential partner cyclin A are present in the nucleus in G1 and S phase and therefore available for DNA replication. In accordance with data obtained inXenopusegg extracts we observed that Cdk2 kinase activity is low and stable during the entire cycle. However, in contrast with thisin vitrosystem in which Cdk2 activity is required for the onset of DNA replication, the specific inhibition of Cdk2 kinase by microinjection of the catalytically inactive Cdk2-K33R or the inhibitor p21^Cip1does not prevent DNA replication. Because olomoucine, DMAP, and emetine treatments did not preclude DNA synthesis, neither cyclin A/Cdk1 nor cyclin B/Cdk1 kinase activities are necessary to replace the absence of Cdk2 kinase in promoting DNA replication. These data suggest that during early embryogenesis Cdks activities, in particular Cdk2, are dispensablein vivofor the initiation step of DNA replication. However, the specific localization of Cdk2 in the nucleus from the beginning of M phase to the end of S phase suggests its involvement in other mechanisms regulating DNA replication such as inhibition of DNA re-replication and/or that its regulating role is achieved through a pathway independent of the kinase activity. We further demonstrate that even after inhibition of Cdk activities, the permeabilization of the nuclear membrane is required to allow a second round of DNA replication. However, in contrast toXenopusegg extracts, re-replication can take place in the absence of DMAP-sensitive kinase.     

Nuclear dynamics of PCNA in DNA replication and repair

The DNA polymerase processivity factor proliferating cell nuclear antigen (PCNA) is central to both DNA replication and repair. The ring-shaped homotrimeric PCNA encircles and slides along double-stranded DNA, acting as a "sliding clamp" that localizes proteins to DNA. We determined the behavior of green fluorescent protein-tagged human PCNA (GFP-hPCNA) in living cells to analyze its different engagements in DNA replication and repair. Photobleaching and tracking of replication foci revealed a dynamic equilibrium between two kinetic pools of PCNA, i.e., bound to replication foci and as a free mobile fraction. To simultaneously monitor PCNA action in DNA replication and repair, we locally inflicted UV-induced DNA damage. A surprisingly longer residence time of PCNA at damaged areas than at replication foci was observed. Using DNA repair mutants, we showed that the initial recruitment of PCNA to damaged sites was dependent on nucleotide excision repair. Local accumulation of PCNA at damaged regions was observed during all cell cycle stages but temporarily disappeared during early S phase. The reappearance of PCNA accumulation in discrete foci at later stages of S phase likely reflects engagements of PCNA in distinct genome maintenance processes dealing with stalled replication forks, such as translesion synthesis (TLS). Using a ubiquitination mutant of GFP-hPCNA that is unable to participate in TLS, we noticed a significantly shorter residence time in damaged areas. Our results show that changes in the position of PCNA result from de novo assembly of freely mobile replication factors in the nucleoplasmic pool and indicate different binding affinities for PCNA in DNA replication and repair.     

Plasma cell proliferation in the chicken Harderian gland

Studies to examine the percentages of proliferating plasma cells (PPC) in the Harderian gland (HG) were carried out in chicks between 5 and 12 weeks of age. Two methods, 5-bromo-2'-deoxyuridine (BrdUrd) incorporation into DNA and flow cytometric analysis of propidium iodide (PI) stained cells, were employed in control and emetine dihydrochloride treated birds. Flow cytometric analysis of PI stained cells showed the percentages of plasma cells in S phase were highest between 6 and 8 weeks of age. After this period of time, the number of S phase plasma cells decreased and remained low through 12 weeks of age. The lowest percentages of plasma cells in G0 + G1 were found at 6 and 8 weeks of age, and all ages had equal percentages of plasma cells in G2 + M phase. After administration of the protein synthesis inhibitor emetine dihydrochloride a common pattern of plasma cell depletion and repopulation in the HG was observed. At 3 and 5 days post-treatment the plasma cell population in the gland decreased and by 7 days post-treatment repopulation of the gland with plasma cells had taken place. Anti-BrdUrd staining of frozen sections revealed that the number of PPC were decreased at 3 days after emetine treatment but were as high as, or higher than, controls at 5 and 7 days post-treatment. Flow cytometric analysis indicated that some birds were more severely affected by emetine. Namely, the percentages of plasma cells in S phase were lower at 3 and 5 days post-treatment. Even though most birds were severely affected by emetine treatment during the experiments, they possessed a cell population with the proliferative capacity to quickly repopulate the HG by 7 days post-emetine treatment.     

Detection of replication initiation by a replicon family in DNA of synchronized pea (Pisum sativum) root cells using benzoylated naphthoylated DEAE-cellulose chromatography

Fractionated replicating DNA from pea was obtained from both synchronized cells just starting replication and from carbohydrate-starved cells ending replication. Benzoylated naphthoylated DEAE-cellulose chromatography of pulse-labeled DNA digested with EcoR I gave evidence that a family of replicons initiated replication 45 to 60 min after synchronized cells were released from the G₁/S phase boundary. DNA from cells labeled in late S phase, on the other hand, showed no signs of additional replication initiations before entering G₂ phase. Results with DNA from both early and late S phase cells comply with a model based on the premise that with short pulses of [³H]-thymidine the isotope is localized at replication forks and that longer pulses label both replication forks and recently replicated segments of double-stranded DNA. The model applies only to DNA subjected to fragmentation before chromatography.The results also suggest that benzoylated naphthoylated DEAE-cellulose chromatography is a useful means to isolate origins and replication forks from synchronized plant cells.     

Multiple sites of replication initiation in the human beta-globin gene locus

The cell cycle-dependent, ordered assembly of protein prereplicative complexes suggests that eukaryotic replication origins determine when genomic replication initiates. By comparison, the factors that determine where replication initiates relative to the sites of prereplicative complex formation are not known. In the human globin gene locus previous work showed that replication initiates at a single site 5′ to the β-globin gene when protein synthesis is inhibited by emetine. The present study has examined the pattern of initiation around the genetically defined β-globin replicator in logarithmically growing HeLa cells, using two PCR-based nascent strand assays. In contrast to the pattern of initiation detected in emetine-treated cells, analysis of the short nascent strands at five positions spanning a 40 kb globin gene region shows that replication initiates at more than one site in non-drug-treated cells. Quantitation of nascent DNA chains confirmed that replication begins at several locations in this domain, including one near the initiation region (IR) identified in emetine-treated cells. However, the abundance of short nascent strands at another initiation site ~20 kb upstream is ~4-fold as great as that at the IR. The latter site abuts an early S phase replicating fragment previously defined at low resolution in logarithmically dividing cells.     

Immunofluorescent visualization of DNA replication sites within nuclei of Chinese hamster ovary cells

Summary The spatial distribution of replication sites was studied by a sensitive method in cells cultured in vitro. Exponentially growing Chinese hamster ovary cells were permeabilized and pulse labeled in the presence of deoxyribonucleoside triphosphates, dTTP being replaced by biotin-11-dUTP as a substrate for DNA replication. The distribution of replication sites was visualized in isolated nuclei by fluorescent microscopy of samples taken periodically after short-term (2 min) in vitro labeling and pulse-chase experiments. Propidium iodide and 4,6-diamino-2-pheny-lindole served as fluorescent probes for total cellular DNA. Avidin-fluorescein isothiocyanate and biotinylated goat antiavidin antibody were used in an amplification procedure to fluorescently label the incorporated biotin-11-dUTP. Similar experiments using synchronized cells showed the distribution of replicons at different stages of S phase.     

Immunofluorescent visualization of DNA replication sites within nuclei of Chinese hamster ovary cells

The spatial distribution of replication sites was studied by a sensitive method in cells cultured in vitro. Exponentially growing Chinese hamster ovary cells were permeabilized and pulse labeled in the presence of deoxyribonucleoside triphosphates, dTTP being replaced by biotin-11-dUTP as a substrate for DNA replication. The distribution of replication sites was visualized in isolated nuclei by fluorescent microscopy of samples taken periodically after short-term (2 min) in vitro labeling and pulse-chase experiments. Propidium iodide and 4,6-diamino-2-phenylindole served as fluorescent probes for total cellular DNA. Avidin-fluorescein isothiocyanate and biotinylated goat antiavidin antibody were used in an amplification procedure to fluorescently label the incorporated biotin-11-dUTP. Similar experiments using synchronized cells showed the distribution of replicons at different stages of S phase.     

Initiation of DNA replication at a nuclear matrix-attached chromatin fraction

It is still unclear what nuclear components support initiation of DNA replication. To address this issue, we developed a cell-free replication system in which the nuclear matrix along with the residual matrix-attached chromatin was used as a substrate for DNA replication. We found out that initiation occurred at late G1 residual chromatin but not at early G1 chromatin and depended on cytosolic and nuclear factors present in S phase cells but not in G1 cells. Initiation of DNA replication occurred at discrete replication foci in a pattern typical for early S phase. To prove that the observed initiation takes place at legitimate DNA replication origins, the in vitro synthesized nascent DNA strands were isolated and analyzed. It was shown that they were enriched in sequences from the core origin region of the early firing, dihydrofolate reductase origin of replication ori-beta and not in distal to the origin sequences. A conclusion is drawn that initiation of DNA replication occurs at discrete sub-chromosomal structures attached to the nuclear matrix.     

Dynamics of DNA replication factories in living cells

DNA replication occurs in microscopically visible complexes at discrete sites (replication foci) in the nucleus. These foci consist of DNA associated with replication machineries, i.e., large protein complexes involved in DNA replication. To study the dynamics of these nuclear replication foci in living cells, we fused proliferating cell nuclear antigen (PCNA), a central component of the replication machinery, with the green fluorescent protein (GFP). Imaging of stable cell lines expressing low levels of GFP-PCNA showed that replication foci are heterogeneous in size and lifetime. Time-lapse studies revealed that replication foci clearly differ from nuclear speckles and coiled bodies as they neither show directional movements, nor do they seem to merge or divide. These four dimensional analyses suggested that replication factories are stably anchored in the nucleus and that changes in the pattern occur through gradual, coordinated, but asynchronous, assembly and disassembly throughout S phase.     

Differential activation of intra-S-phase checkpoint in response to tripchlorolide and its effects on DNA replication

DNA replication is tightly regulated during the S phase of the cell cycle, and the activation of the intra-S-phase checkpoint due to DNA damage usually results in arrest of DNA synthesis. However, the molecular details about the correlation between the checkpoint and regulation of DNA replication are still unclear. To investigate the connections between DNA replication and DNA damage checkpoint, a DNA-damage reagent, tripchlorolide, was applied to CHO (Chinese ovary hamster) cells at early- or middle-stages of the S phase. The early-S-phase treatment with TC signifi-cantly delayed the progression of the S phase and caused the phosphorylation of the Chk 1 checkpoint protein, whereas the middle-S-phase treatment only slightly slowed down the progression of the S phase. Furthermore, the analysis of DNA replication patterns revealed that replication pattern II was greatly prolonged in the cells treated with the drug during the early-S phase, whereas the late-replication patterns of these cells were hardly detected, suggesting that the activation of the intra-S-phase checkpoint inhibits the late-origin firing of DNA replication. We conclude that cells at different stages of the S phase are differentially sensitive to the DNA-damage reagent, and the activation of the intra-S-phase checkpoint blocks the DNA replication progression in the late stage of S phase.     

The recovery of normal DNA replication kinetics in ultraviolet-irradiated Chinese hamster cells

The kinetics of DNA replication were analyzed in the second S phase following UV irradiation of Chinese hamster ovary cells synchronized at the beginning of S phase. The cells were synchronized by treating cells selected in mitosis with hydroxyurea for 9 h. Following UV irradiation, the cells were allowed to progress until the next mitosis; at which time they were resynchronized at the beginning of the second S phase by the same procedure. The kinetics of DNA replication were determined by measuring the proportion of DNA which achieved hybrid buoyant density on CsCl density gradients as a function of the time of incubation in the presence of 5-bromodeoxyuridine.The results of these experiments showed that even though the rate of DNA replication is substantially depressed during the first S phase following UV irradiation with a fluence of 5 J/m², the rate has recovered to the extent that it is indistinguishable from the unirradiated control by the time the cells have entered their second S phase. It was concluded from these observations that the lesions in DNA which caused the rate of DNA replication to be initially depressed during the first S phase have been either removed or modified such that they no longer are able to cause a reduction in the rate of DNA replication in the second S phase following UV irradiation.     

Visualising chromosomal replication sites and replicons in mammalian cells

The precise regulation of DNA replication is fundamental to the preservation of intact genomes during cell proliferation. Our understanding of this process has been based traditionally on a combination of techniques including biochemistry, molecular biology and cell biology. In this report we describe how the analysis of the S phase in mammalian cells using classical cell biology techniques has contributed to our understanding of the replication process. We describe traditional and state-of-the-art protocols for imaging sites of DNA synthesis in nuclei and the organisation of active replicons along DNA, as visualised on individual DNA fibres. We evaluate how the different approaches inform our understanding of the replication process, placing particular emphasis on ways in which the higher order chromatin structures and the spatial architecture of replication sites contribute to the orderly activation of defined regions of the genome at precise times of S phase.     

Estimating the Total Rate of DNA Replication Using Branching Processes

Increasing the knowledge of various cell cycle kinetic parameters, such as the length of the cell cycle and its different phases, is of considerable importance for several purposes including tumor diagnostics and treatment in clinical health care and a deepened understanding of tumor growth mechanisms. Of particular interest as a prognostic factor in different cancer forms is the S phase, during which DNA is replicated. In the present paper, we estimate the DNA replication rate and the S phase length from bromodeoxyuridine-DNA flow cytometry data. The mathematical analysis is based on a branching process model, paired with an assumed gamma distribution for the S phase duration, with which the DNA distribution of S phase cells can be expressed in terms of the DNA replication rate. Flow cytometry data typically contains rather large measurement variations, however, and we employ nonparametric deconvolution to estimate the underlying DNA distribution of S phase cells; an estimate of the DNA replication rate is then provided by this distribution and the mathematical model.     

Mapping replicational sites in the eucaryotic cell nucleus

We have used fluorescent microscopy to map DNA replication sites in the interphase cell nucleus after incorporation of biotinylated dUTP into permeabilized PtK-1 kangaroo kidney or 3T3 mouse fibroblast cells. Discrete replication granules were found distributed throughout the nuclear interior and along the periphery. Three distinct patterns of replication sites in relationship to chromatin domains in the cell nucleus and the period of S phase were detected and termed type I (early to mid S), type II (mid to late S) and type III (late S). Similar patterns were seen with in vivo replicated DNA using antibodies to 5-bromodeoxyuridine. Extraction of the permeabilized cells with DNase I and 0.2 M ammonium sulfate revealed a striking maintenance of these replication granules and their distinct intranuclear arrangements with the remaining nuclear matrix structures despite the removal of greater than 90% of the total nuclear DNA. The in situ prepared nuclear matrix structures also incorporated biotinylated dUTP into replication granules that were indistinguishable from those detected within the intact nucleus.     

Dependence of timing of mitotic events on the rate of protein synthesis and DNA replication in sea urchin early cleavages

Abstract. To understand what processes affect the cell-cycle timing of mitotic events in early cleavage cycles of sea urchin embryos, a study was made on the effects of (a) reducing protein synthesis with emetine and (b) DNA replication with aphidi-colin, on the timing of nuclear envelope breakdown, anaphase onset and cytokinesis. When protein synthesis was slightly inhibited by administration of emetine, the delay in the mitotic events increased, with an increase in the delay in accumulation of proteins up to the levels to which cells must synthesize the proteins to execute the cleavage. This indicated that protein synthesis affects the timing of mitotic events. The delay in cleavage cycles caused by a slight inhibition of DNA replication with aphidicolin was in proportion to the concentration of aphidicolin administered, suggesting that DNA replication also affects the timing of mitotic events. Furthermore, it was confirmed that accumulation of the proteins to the levels required for execution of the first cleavage precedes completion of DNA replication as a requirement for execution of the first cleavage. These results imply the existence of process(es) affected by protein synthesis that are included in a feedback control system which prevents the initiation of mitosis until after the completion of DNA replication; it is the characteristic of a cell-cycle control system that has been predicted theoretically.     

Localization of human Mcm10 is spatially and temporally regulated during the S phase

Mcm10 (Dna43) is an essential protein for the initiation of DNA replication in Saccharomyces cerevisiae. Recently, we identified a human Mcm10 homolog and found that it is regulated by proteolysis and phosphorylation in a cell cycle-dependent manner and that it binds chromatin exclusively during the S phase of the cell cycle. However, the precise roles that Mcm10 plays are still unknown. To study the localization dynamics of human Mcm10, we established HeLa cell lines expressing green fluorescent protein (GFP)-tagged Mcm10. From early to mid-S phase, GFP-Mcm10 appeared in discrete nuclear foci. In early S phase, several hundred foci appeared throughout the nucleus. In mid-S phase, the foci appeared at the nuclear periphery and nucleolar regions. In the late S and G phases, GFP-Mcm10 was localized to nucleoli. Although (2)the distributions of GFP-Mcm10 during the S phase resembled those of replication foci, GFP-Mcm10 foci did not colocalize with sites of DNA synthesis in most cases. Furthermore, the transition of GFP-Mcm10 distribution patterns preceded changes in replication foci patterns or proliferating cell nuclear antigen foci patterns by 30-60 min. These results suggest that human Mcm10 is temporarily recruited to the replication sites 30-60 min before they replicate and that it dissociates from chromatin after the activation of the prereplication complex.     

Claspin,a Chk1-regulatory protein,monitors DNA replication on chromatin independently of RPA,ATR, and Rad17

Claspin is required for the ATR-dependent activation of Chk1 in Xenopus egg extracts containing incompletely replicated DNA. We show here that Claspin associates with chromatin in a regulated manner during S phase. Binding of Claspin to chromatin depends on the pre-replication complex (pre-RC) and Cdc45 but not on replication protein A (RPA). These dependencies suggest that binding of Claspin occurs around the time of initial DNA unwinding at replication origins. By contrast, both ATR and Rad17 require RPA for association with DNA. Claspin, ATR, and Rad17 all bind to chromatin independently. These findings suggest that Claspin plays a role in monitoring DNA replication during S phase. Claspin, ATR, and Rad17 may collaborate in checkpoint regulation by detecting different aspects of a DNA replication fork.