Yeast L double-stranded ribonucleic acid is synthesized during the G1 phase but not the S phase of the cell cycle.

The cytoplasm of Saccharomyces cerevisiae contains two major classes of protein-encapsulated double-stranded ribonucleic acids (dsRNA's), L and M. Replication of L and M dsRNA's was examined in cells arrested in the G1 phase by either alpha-factor, a yeast mating pheromone, or the restrictive temperature for a cell cycle mutant (cdc7). [3H]uracil was added during the arrest periods to cells prelabeled with [14C]uracil, and replication was monitored by determining the ratio of 3H/14C for purified dsRNA's. Like mitochondrial deoxyribonucleic acid, both L and M dsRNA's were synthesized in the G1 arrested cells. The replication of L dsRNA was also examined during the S phase, using cells synchronized in two different ways. Cells containing the cdc7 mutation, treated sequentially with alpha-factor and then the restrictive temperature, enter a synchronous S phase when transferred to permissive temperature. When cells entered the S phase, synthesis of L dsRNA ceased, and little or no synthesis was detected throughout the S phase. Synthesis of L dsRNA was also observed in G1 phase cells isolated from asynchronous cultures by velocity centrifugation. Again, synthesis ceased when cells entered the S phase. These results indicate that L dsRNA replication is under cell cycle control. The control differs from that of mitochondrial deoxyribonucleic acid, which replicates in all phases of the cell cycle, and from that of 2-micron DNA, a multiple-copy plasmid whose replication is confined to the S phase.     

Purification of a cellular replication factor, RF-C, that is required for coordinated synthesis of leading and lagging strands during simian virus 40 DNA replication in vitro.

Cell extracts (S100) derived from human 293 cells were separated into five fractions by phosphocellulose chromatography and monitored for their ability to support simian virus 40 (SV40) DNA replication in vitro in the presence of purified SV40 T antigen. Three fractions, designated I, IIA, and IIC, were essential. Fraction IIC contained the known replication factors topoisomerases I and II, but in addition contained a novel replication factor called RF-C. The RF-C activity, assayed in the presence of I, IIA, and excess amounts of purified topoisomerases, was detected in both cytosol and nuclear fractions, but was more abundant in the latter fraction. RF-C was purified from the 293 cell nuclear fraction to near homogeneity by conventional column chromatography. The reconstituted reaction mix containing purified RF-C could replicate SV40 origin-containing plasmid DNA more efficiently than could the S100 extract, and the products were predominantly completely replicated, monomer molecules. Interestingly, in the absence of RF-C, early replicative intermediates accumulated and subsequent elongation was aberrant. Hybridization studies with strand-specific, single-stranded M13-SV40 DNAs showed that in the absence of RF-C, abnormal DNA synthesis occurred preferentially on the lagging strand, and leading-strand replication was inefficient. These products closely resembled those previously observed for SV40 DNA replication in vitro in the absence of proliferating-cell nuclear antigen. These results suggest that an elongation complex containing RF-C and proliferating-cell nuclear antigen is assembled after formation of the first nascent strands at the replication origin. Subsequent synthesis of leading and lagging strands at a eucaryotic DNA replication fork can be distinguished by different requirements for multiple replication components, but we suggest that even though the two polymerases function asymmetrically, they normally progress coordinately.     

The effects of different thymidine concentrations on DNA replication in pea-root cells synchronized by a protracted 5-fluorodeoxyuridine treatment

Single-cell and DNA fiber autoradiography, cytophotometry and velocity sedimentation in alkaline sucrose gradients were used to analyse DNA replication and nascent replicon maturation in 5-fluorodeoxyuridine (FUdR)-synchronized cells of Pisum sativum. The replicon size was not significantly changed by the protracted FUdR treatment. When the synchronized cells were released from the inhibitor, labeled with [³H]TdR for 30 min, and chased in medium containing 1 × 10⁻⁶ M or lower concentrations of cold thymidine, DNA replication stopped after approx. 25% of the genome had replicated, and the nascent strands failed to grow above 9–12 × 10⁶ D single-stranded (ss) DNA. When the cells were chased in medium with 1 × 10⁻⁵ M cold thymidine, the DNA content of the labeled cells steadily increased with time and the size of the nascent molecules grew continuously until replicon size was achieved; then they were accumulated at replicon size until the cells arrived in late S or G2. When the FUdR-synchronized cells were chased in medium containing 1 × 10⁻⁴ M cold thymidine, the size of the nascent strands increased continuously with time, indicating that some neighbouring nascent replicons were joined as soon as they completed their replication. These observations led us to postulate that in FUdR-synchronized cells the rates of chain elongation, cell progression through the S phase and nascent replicon maturation are controlled by thymidine availability.     

S-phase-dependent cell cycle disturbances caused by Aleutian mink disease parvovirus.

We examined replication of the autonomous parvovirus Aleutian mink disease parvovirus (ADV) in relation to cell cycle progression of permissive Crandell feline kidney (CRFK) cells. Flow cytometric analysis showed that ADV caused a composite, binary pattern of cell cycle arrest. ADV-induced cell cycle arrest occurred exclusively in cells containing de novo-synthesized viral nonstructural (NS) proteins. Production of ADV NS proteins, indicative of ADV replication, was triggered during S-phase traverse. The NS+ cells that were generated during later parts of S phase did not undergo cytokinesis and formed a distinct population, termed population A. Formation of population A was not prevented by VM-26, indicating that these cells were arrested in late S or G2 phase. Cells in population A continued to support high-level ADV DNA replication and production of infectious virus after the normal S phase had ceased. A second, postmitotic, NS+ population (termed population B) arose in G0/G1, downstream of population A. Population B cells were unable to traverse S phase but did exhibit low-level DNA synthesis. Since the nature of this DNA synthesis was not examined, we cannot at present differentiate between G1 and early S arrest in population B. Cells that became NS+ during S phase entered population A, whereas population B cells apparently remained NS- during S phase and expressed high NS levels postmitosis in G0/G1. This suggested that population B resulted from leakage of cells with subthreshold levels of ADV products through the late S/G2 block and, consequently, that the binary pattern of ADV-induced cell cycle arrest may be governed merely by viral replication levels within a single S phase. Flow cytometric analysis of propidium iodide fluorescence and bromodeoxyuridine uptake showed that population A cells sustained significantly higher levels of DNA replication than population B cells during the ADV-induced cell cycle arrest. Therefore, the type of ADV-induced cell cycle arrest was not trivial and could have implications for subsequent viral replication in the target cell.     

In the higher plant Pisum sativum maturation of nascent DNA is blocked by cycloheximide, but only after 4-8 replicons are joined.

Velocity sedimentation in alkaline sucrose gradients, single cell autoradiography and cytophotometry were used to determine if protein synthesis is required for the maturation of nascent replicons to chromosomal-sized molecules in cultured pea-root cells. The results obtained showed that cycloheximide at 5 and 10 microgram/ml, added either before or during labeling with tritiated thymidine, blocked maturation of nascent DNA at an intermediate size of 72-140 X 10(6) daltons single-stranded DNA. To reach this size, nascent replicons - which are 18 X 10(6) daltons single-stranded DNA each - were replicated and groups of 4-8 replicons were joined even though protein synthesis was reduced to 15% of the control. Further maturation of the nascent molecules to chromosomal size, however, was prevented and this resulted in the accumulation of nascent molecules in the 72-140 X 10(6) daltons range. The experiments also showed that the joining of nascent replicons is not an absolute function of late S or G2 phase of the cell cycle, since cells treated with cycloheximide and blocked in mid-S phase had nascent DNA of a size corresponding to 4-8 joined replicons. Finally, the results support the hypothesis that at least one step in the process of nascent DNA maturation may require replication, during late-S phase, of DNA segments that are interspersed within replicon-clusters that replicate early in the 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.     

Mimosine reversibly arrests cell cycle progression at the G1-S phase border

It has previously been demonstrated that the compound mimosine inhibits cell cycle traverse in late G1 phase prior to the onset of DNA synthesis (Hoffman BD, Hanauske-Abel HM, Flint A, Lalande M: Cytometry 12:26-32, 1991; Lalande M: Exp Cell Res 186:332-339, 1990). These results were obtained by using flow cytometric analysis of DNA content to compare the effects of mimosine on cell cycle traverse with those of aphidicolin, an inhibitor of DNA polymerase alpha activity. We have now measured the incorporation of bromodeoxyuridine into lymphoblastoid cells by flow cytometry to determine precisely where the two inhibitors act relative to the initiation of DNA synthesis. It is demonstrated here that mimosine arrests cell cycle progression at the G1-S phase border. The onset of DNA replication occurs within 15 min of releasing the cells from the mimosine block. In contrast, treatment with aphidicolin results in the accumulation of cells in early S phase. These results indicate that mimosine is a suitable compound for affecting the synchronous release of cells from G1 into S phase and for analyzing the biochemical events associated with this cell cycle phase transition.     

Analysis of a Chinese hamster temperature-sensitive cell cycle mutant arrested in early S phase

E36 ts24 is a temperature-sensitive cell cycle mutant which has been derived from the Chinese hamster lung cell line E36. This mutant is arrested in phase S when incubated at the restrictive temperature (40.3 degrees C) for growth. At this temperature, proliferation of the mutant cells ceases after 10 h. About 2 h earlier, DNA synthesis is arrested. These kinetic studies indicate that the execution point of the mutant cells is in early S phase well beyond the G1/S boundary. The pattern of replication bands in E36 ts24 cell grown for 9 h at 40.3 degrees C strengthen the kinetic studies and map the execution point to early S phase. The exact point of arrest of the mutant cells in phase S was mapped in early S phase near the execution point. At the point of arrest the cells continue to synthesize DNA at at a high rate but practically all of the newly synthesized DNA is degraded. This high rate of DNA degradation is limited to nascent DNA at the point of arrest. In the presence of 5-bromodeoxyuridine (5-BudR), the last E36 ts24 cells which reach mitosis at the restrictive temperature for growth show asymmetric replication bands which illustrate DNA degradation and resynthesis occurring in these cells at 40.3 degrees C.     

Leading strand synthesis of R1 plasmid replication in vitro is primed by primase alone at a specific site downstream of oriR

By using an in vitro system for R1 plasmid replication dependent on a plasmid-encoded repA protein and host dnaA protein, 5' ends of the nascent leading strand were located at positions 1986-1992, some 380 base pair downstream of oriR. Analyses of early replication intermediates generated in vitro in the presence of dideoxy TTP also indicated that replication initiates about 400 base pair downstream of oriR and proceeds unidirectionally. When a 418-base single-stranded DNA from position 1778 to 2195, derived from the leading strand template, was cloned onto an M13 vector, the chimeric single-stranded phage could be replicated in vitro with only single-stranded DNA binding protein, primase (dnaG gene product), and DNA polymerase III holoenzyme. Furthermore, the priming occurred at a site identical to leading strand initiation. These results strongly suggest that the leading strand synthesis is primed by primase alone. The lagging strand synthesis is specifically terminated at position 1515 or 1516 within oriR, preventing further leftward fork movement. Based on these results, a scheme of R1 plasmid replication is presented.     

Human DNA polymerase epsilon colocalizes with proliferating cell nuclear antigen and DNA replication late, but not early, in S phase.

DNA polymerase epsilon (pol epsilon) has been implicated in DNA replication, DNA repair, and cell cycle control, but its precise roles are unclear. When the subcellular localization of human pol epsilon was examined by indirect immunofluorescence, pol epsilon appeared in discrete nuclear foci that colocalized with proliferating cell nuclear antigen (PCNA) foci and sites of DNA synthesis only late in S phase. Early in S phase, pol epsilon foci were adjacent to PCNA foci. In contrast to PCNA foci that were only present in S phase, pol epsilon foci were present throughout mitosis and the G(1) phase of cycling cells. It is hypothesized from these observations that pol epsilon and PCNA have separate but associated functions early in S phase and that pol epsilon participates with PCNA in DNA replication late in S phase.     

DNA damage bypass operates in the S and G2 phases of the cell cycle and exhibits differential mutagenicity

Translesion DNA synthesis (TLS) employs low-fidelity DNA polymerases to bypass replication-blocking lesions, and being associated with chromosomal replication was presumed to occur in the S phase of the cell cycle. Using immunostaining with anti-replication protein A antibodies, we show that in UV-irradiated mammalian cells, chromosomal single-stranded gaps formed in S phase during replication persist into the G2 phase of the cell cycle, where their repair is completed depending on DNA polymerase ζ and Rev1. Analysis of TLS using a high-resolution gapped-plasmid assay system in cell populations enriched by centrifugal elutriation for specific cell cycle phases showed that TLS operates both in S and G2. Moreover, the mutagenic specificity of TLS in G2 was different from S, and in some cases overall mutation frequency was higher. These results suggest that TLS repair of single-stranded gaps caused by DNA lesions can lag behind chromosomal replication, is separable from it, and occurs both in the S and G2 phases of the cell cycle. Such a mechanism may function to maintain efficient replication, which can progress despite the presence of DNA lesions, with TLS lagging behind and patching regions of discontinuity.     

The replication timing of the amplified dihydrofolate reductase genes in the Chinese hamster ovary cell line CHOC 400

We have examined the timing of replication of the amplified dihydrofolate reductase genes in the methotrexate-resistant Chinese hamster ovary cell line CHOC 400 using two synchronization procedures. DNA replicated in the presence of 5-bromodeoxyuridine was collected from cells of various times during the DNA synthesis phase and the extent of replication for defined sequences was determined by Southern blotting analysis of CsCl density gradient fractions. We report that under these conditions the DHFR gene replicates throughout the course of S phase in a mode similar to the bulk of the replicated genomic DNA. This contrasts with previous data that shows the non-amplified DHFR gene replicates during the first quarter of S phase. Therefore, we conclude that gene amplification alters the replication timing of the DHFR gene in CHOC 400 cells.     

DNA replication and spindle checkpoints cooperate during S phase to delay mitosis and preserve genome integrity

Deoxyribonucleic acid (DNA) replication and chromosome segregation must occur in ordered sequence to maintain genome integrity during cell proliferation. Checkpoint mechanisms delay mitosis when DNA is damaged or upon replication stress, but little is known on the coupling of S and M phases in unperturbed conditions. To address this issue, we postponed replication onset in budding yeast so that DNA synthesis is still underway when cells should enter mitosis. This delayed mitotic entry and progression by transient activation of the S phase, G2/M, and spindle assembly checkpoints. Disabling both Mec1/ATR- and Mad2-dependent controls caused lethality in cells with deferred S phase, accompanied by Rad52 foci and chromosome missegregation. Thus, in contrast to acute replication stress that triggers a sustained Mec1/ATR response, multiple pathways cooperate to restrain mitosis transiently when replication forks progress unhindered. We suggest that these surveillance mechanisms arose when both S and M phases were coincidently set into motion by a unique ancestral cyclin–Cdk1 complex.     

High-resolution mapping of the origin of DNA replication in the hamster dihydrofolate reductase gene domain by competitive PCR.

By the use of a highly sensitive mapping procedure allowing the identification of the start sites of DNA replication in single-copy genomic regions of untreated, exponentially growing cultured cells (M. Giacca, L. Zentilin, P. Norio, S. Diviacco, D. Dimitrova, G. Contreas, G. Biamonti, G. Perini, F. Weighardt, S. Riva, and A. Falaschi, Proc. Natl. Acad. Sci. USA 91:7119-7123, 1994), the pattern of DNA replication of the Chinese hamster dihydrofolate reductase (DHFR) gene domain was investigated. The method entails the purification of short stretches of nascent DNA issuing from DNA replication origin regions and quantification, within this sample, of the abundance of different adjacent segments by competitive PCR. Distribution of marker abundance peaks around the site from which newly synthesized DNA had emanated. The results obtained by analysis of the genomic region downstream of the DHFR single-copy gene in asynchronous cultures of hamster CHO K1 cells are consistent with the presence of a single start site for DNA replication, located approximately 17 kb downstream of the gene. This site is coincident with the one detected by other studies using different techniques in CHO cell lines containing an amplified DHFR gene domain.     

Selective interactions of human kin17 and RPA proteins with chromatin and the nuclear matrix in a DNA damage- and cell cycle-regulated manner

Several proteins involved in DNA synthesis are part of the so-called 'replication factories' that are anchored on non-chromatin nuclear structures. We report here that human kin17, a nuclear stress-activated protein, associates with both chromatin and non-chromatin nuclear structures in a cell cycle- and DNA damage-dependent manner. After L-mimosine block and withdrawal we observed that kin17 protein was recruited in the nucleus during re-entry and progression through S phase. These results are consistent with a role of kin17 protein in DNA replication. About 50% of the total amount of kin17 protein was detected on nuclear structures and could not be released by detergents. Furthermore, the amount of kin17 protein greatly increased in both G(1)/S and S phase-arrested cells in fractions containing proteins anchored to nuclear structures. The detection of kin17 protein showed for the first time its preferential assembly within non-chromatin nuclear structures in G(1)/S and S phase-arrested cells, while the association with these structures was found to be less stable in the G(2)/M phase, as judged by fractionation of human cells and immunostaining. In asynchronous growing cells, kin17 protein interacted with both chromatin DNA and non-chromatin nuclear structures, while in S phase-arrested cells it interacted mostly with non-chromatin nuclear structures, as judged by DNase I treatment and in vivo UV cross-linking. In the presence of DNA damage in S phase cells, the distribution of kin17 protein became mainly associated with chromosomal DNA, as judged by limited formaldehyde cross-linking of living cells. The physical interaction of kin17 protein with components of the nuclear matrix was confirmed and visualized by indirect immunofluorescence and immunoelectron microscopy. Our results indicate that, during S phase, a fraction of the human kin17 protein preferentially associates with the nuclear matrix, a fundamentally non-chromatin higher order nuclear structure, and to chromatin DNA in the presence of DNA damage.     

The effects of inhibitors of DNA biosynthesis on the cytotoxicity of 6-thioguanine

The effects of several metabolic inhibitors of DNA synthesis on the antiproliferative activity of 6-thioguanine (6-TG) were examined using cultured L1210 leukemia cels. The presence of hydroxyurea (HU), 1-beta-D-arabinofuranosylcytosine (araC), or 5-fluorodeoxyuridine (FUdR) in cultures of L1210 leukemic cells during exposure of 6-TG did not increase the degree of inhibition of cellular replication produced by the 6-thiopurine, but instead partially protected cells against the delayed cytotoxicity of 6-TG, implying that DNA replication was essential for the expression of cytotoxicity by the purine antimetabolite. Consistent with these results was the finding that synchronized L1210 cells exposed to 6-TG were the most susceptible to the cytotoxic action of the 6-thiopurine during G1/S and S phase. However, G2 phase cells were also sensitive to 6-TG indicating that at least two metabolic lesions are responsible for the production of cytotoxicity. Alkaline sucrose gradient sedimentation of L1210 cells exposed to 6-TG revealed that the purine analog causes structural changes in DNA suggesting that these hitherto unreported lesions may be involved in the cytotoxicity caused by this agent.     

Synthesis of high molecular weight DNA strands during S phase

The organization of the mammalian S phase was studied in synchronized mouse embryo cells in terms of the spatial relationship between replication units whose synthesis is initiated at different times in S phase and the rate of assimilation of replication units into high molecular weight DNA strands.The formation of high molecular weight nascent DNA strands several replication units in length was analyzed by velocity sedimentation in alkaline sucrose gradients and by isopycnic centrifugation in alkaline Cs₂SO₄/CsCl gradients. Differential labeling with an isotopic and a density label shows that replication units synthesized at different stages of the S phase are not found within the same high molecular weight polynucleotide strand. It is thus concluded that replication units duplicated at different stages of the S phase are spatially organized in clusters along the mammalian genome.The rate of formation of high molecular weight nascent DNA strands is at least 4 to 8 times slower than that predicted from the spatial organization of replication units and the rate of chain growth within replication units. It is concluded that the process of joining of the completed nascent strands of adjacent replication units plays a major role in the rate of completion of high molecular weight strands.