Gene replication in the presence of aphidicolin

DNA replication in the nucleus of eukaryotic cells is restricted to the S phase of the cell cycle, and different genes are duplicated at specific times, according to a well-defined temporal order. We have investigated whether activation of initiation sites, in proximity to genes that are replicated in different portions of the S phase, could be detected when synchronized 10T1/2 cells were maintained in aphidicolin (APC), an inhibitor of DNA polymerases alpha and delta. Cells released from confluence arrest into medium containing 2 micrograms/mL APC progressed into the S phase, and nascent DNA accumulated during incubations of 24 and 32 h. Exposure to APC for 40 or 48 h resulted in growth of the radiolabeled DNA into larger molecules. Replicating DNA was isolated in CsCl gradients and probed with 32P-labeled gene probes for early-replicating genes (e.g., Ha-ras, mos, and myc) and a late-replicating gene (VH Ig). DNA replicated during the 24-h incubation in APC was enriched in Ha-ras gene sequences. The VH Ig gene did not replicate in cells incubated for as long as 56 h with APC. The myc and the mos genes were detected after 32 and 40 h in APC, respectively. The myc gene is replicated in 10T1/2 cells after Ha-ras but before mos. Therefore, the order of activation of these genes was conserved in the presence of APC. The delay in replication of myc and mos correlated well with the slowing of DNA replication by APC.     

The temporal order of replication of murine immunoglobulin heavy chain constant region sequences corresponds to their linear order in the genome.

The time of replication during the S phase in a murine erythroleukemia (MEL) cell line was determined for immunoglobulin heavy chain constant region C alpha, C gamma 2b and C mu sequences whose boundaries are defined by EcoR1 restriction endonuclease sites (EcoR1 segments). Logarithmically growing cultures of MEL cells with an S phase of about 7.5 hours were pulse labelled with 20 micrograms/ml of 5-bromodeoxyuridine (BUdR). The cells were then fractionated by centrifugal elutriation into 10-12 distinct populations containing cells in different stages of the cell cycle. Flow microfluorimetric (FMF) analysis of DNA content, measurements of cell volume and autoradiography after 3H-thymidine pulse labelling were used to determine position in the cell cycle. Fractions were pooled to represent four selected intervals of S in which BU-DNA was synthesized for 2.5 hrs or less. Newly replicated DNA which had incorporated BUdR into one strand was isolated, cleaved with EcoR1, and separated on neutral Cs2S04 gradients. Equal amounts of BU-DNA replicated during these four intervals of S were electrophoresed in 0.8% agarose gels, transferred to diazotized aminobenzyloxymethyl paper and hybridized with 32p probes containing the C alpha, C gamma 2b and C mu genes and flanking sequences. The relative amounts of segments replicated were assessed by quantitation of the appropriate bands on the autoradiograms by microdensitometry. The results indicate that the 2.8 kb C alpha, 6.6 kb C gamma 2b and 12 kb C mu EcoR1 segments in these MEL cells replicated during defined intervals of the first half of the S phase. The order of replication of these EcoR1 segments as the cells proceeded through S was C alpha, C gamma 2b, C mu, corresponding to the linear order of the genes determined by restriction endonuclease mapping.     

Cell cycle control of initiation of eukaryotic DNA replication

Eukaryotic DNA replication is confined to a specific portion of the cell cycle (the S phase) and is highly regulated: every segment of the genome is replicated once per S phase, but no segment is normally replicated more than once. How this tight control of replication is accomplished is not known. However, the pace of research into the mechanisms of eukaryotic DNA replication and of cell cycle control has accelerated dramatically within the past few years. Recent investigations provide, for the first time, hints of how control of replication may be coupled at the molecular level to control of the cell cycle. This review is intended to bring these recent investigations to the reader's attention and to speculate about their relationships to each other.(ABSTRACT TRUNCATED AT 250 WORDS)     

Scheduled conversion of replication complex architecture at replication origins of Saccharomyces cerevisiae during the cell cycle

Replication of DNA within Saccharomyces cerevisiae chromosomes is initiated from multiple origins, whose activation follow their own inherent time schedules during the S phase of the cell cycle. It has been demonstrated that a characteristic replicative complex (RC) that includes an origin recognition complex is formed at each origin and shifts between post- and pre-replicative states during the cell cycle. We wanted to determine whether there was an association between this shift in the state of the RC and firing events at replication origins. Time course analyses of RC architecture using UV-footprinting with synchronously growing cells revealed that pre-replicative states at both early and late firing origins appeared simultaneously during late M phase, remained in this state during G(1) phase, and converted to the post-replicative state at various times during S phase. Because the conversion of the origin footprinting profiles and origin firing, as assessed by two-dimensional gel electrophoresis, occurred concomitantly at each origin, then these two events must be closely related. However, conversion of the late firing origin occurred without actual firing. This was observed when the late origin was suppressed in clb5-deficient cells and a replication fork originating from an outside origin replicated the late origin passively. This mechanism ensures that replication at each chromosomal locus occurs only once per cell cycle by shifting existing pre-RCs to the post-RC state, when it is replicated without firing.     

Replication of the dihydrofolate reductase genes on double minute chromosomes in a murine cell line

The purpose of this study is to determine the kinetics of the replication of intrachromosomal versus extrachromosomal amplified dihydrofolate reductase (DHFR) genes. Previous studies reported that the DHFR gene, when carried intrachromosomally on a homogeneously staining region, replicates (as a unit) within the first 2 h of the S phase of the cell cycle. We wished to determine if the extrachromosomal location of the amplified genes carried on double minute chromosomes effects the timing of their replication. Equilibrium cesium chloride ultracentrifugation was used to separate newly replicated (BUdR-labeled) DNA from bulk DNA in a synchronized cell population. Hybridization with the cDNA for the DHFR gene allowed us to determine the period of time within the cell cycle in which the DHFR DNA sequences were replicated. We found that, in contrast to intrachromosomal dihydrofolate reductase genes that uniformly replicate as a unit at the beginning of the S phase of the cell cycle, dihydrofolate reductase genes carried on double minute chromosomes (DMs) replicate throughout the S phase of the cell cycle. These results suggest that control of replication of extrachromosomal DNA sequences may differ from intrachromosomal sequences.     

DNA contents of replication without DNA density labeling

A new method for determining the timing of DNA replication in specific regions of the mammalian genome without the use of DNA density labeling and DNA density centrifugation is described. The method is based on determination of average relative DNA copy numbers in specific genomic regions as cells progress through S phase, and "time of replication" for a specific region is described in terms of the cell's DNA content when the region is replicated. DNA is isolated from synchronized populations of G1 and S phase cells, it is slot-blotted at the same DNA concentration(s) for each population, and it is hybridized with 32P-labeled DNA probes that are specific to the regions of interest. Quantitation of the slot blot autoradiograms and flow cytometric analysis allows determination of (a) average relative DNA copy numbers for the regions of interest in synchronized cell populations, and (b) the average total DNA content in each population of synchronized cells. This information and the flow cytometry histograms are then used to calculate the cellular DNA content at which each region of interest is replicated. The results have a precision of less than or equal to +/- 10% of S phase for Chinese hamster (line CHO) rhodopsin, metallothionein II, the 5'-end of dihydrofolate reductase, the telomeric repeated sequence, pHuR-093 (also located near the centromeres in CHO chromosomes), and the c-Ki-ras family.     

Quantitative analysis of the proliferative activity induced in murine thymocytes by concanavalin A.

A quantitative analysis of the proliferative response induced in murine thymocytes by concanavalin A (Con A) is described. Exogenous 3H-thymidine labels 35 to 40% of the newly incorporated TMP residues under optimal conditions. The density label 5-bromo-2-deoxuridine (BrUdR) does not affect DNA metabolism in this system. With this nucleoside, it is shown that newly synthesized DNA is the result of semi-conservative replication, not repair. Double labeling of DNA provides a monitor for cells traversing the cell cycle (S phase to subsequent S phase). The average cycle time is 12.5 hr, and the shortest cell cycle time is 10 hr. The growing fraction of active cells is about two-thirds. The data show that different subpopulations of thymocytes begin proliferating after various times in culture. Once effectively stimulated by Con A, some of the cells can traverse the cell cycle at least twice more after the mitogen is removed.     

Cell Cycle Arrest of Cdc Mutants and Specificity of the Rad9 Checkpoint

In eucaryotes a cell cycle control called a checkpoint ensures that mitosis occurs only after chromosomes are completely replicated and any damage is repaired. The function of this checkpoint in budding yeast requires the RAD9 gene. Here we examine the role of the RAD9 gene in the arrest of the 12 cell division cycle (cdc) mutants, temperature-sensitive lethal mutants that arrest in specific phases of the cell cycle at a restrictive temperature. We found that in four cdc mutants the cdc rad9 cells failed to arrest after a shift to the restrictive temperature, rather they continued cell division and died rapidly, whereas the cdc RAD cells arrested and remained viable. The cell cycle and genetic phenotypes of the 12 cdc RAD mutants indicate the function of the RAD9 checkpoint is phase-specific and signal-specific. First, the four cdc RAD mutants that required RAD9 each arrested in the late S/G(2) phase after a shift to the restrictive temperature when DNA replication was complete or nearly complete, and second, each leaves DNA lesions when the CDC gene product is limiting for cell division. Three of the four CDC genes are known to encode DNA replication enzymes. We found that the RAD17 gene is also essential for the function of the RAD9 checkpoint because it is required for phase-specific arrest of the same four cdc mutants. We also show that both X- or UV-irradiated cells require the RAD9 and RAD17 genes for delay in the G(2) phase. Together, these results indicate that the RAD9 checkpoint is apparently activated only by DNA lesions and arrests cell division only in the late S/G(2) phase.     

Control of F′lac Replication in Escherichia coli B/r

The timing of replication of an F'lac plasmid during the division cycle of Escherichia coli B/r lac(-)/F'lac was examined in relation to the timing of initiation of chromosome replication. This was accomplished by measuring the induction of beta-galactosidase and the incorporation of radioactive thymidine into cells at different ages in cultures growing exponentially at various rates. In cells growing with interdivision times of 27, 36, and 55 min, the F'lac replicated at various stages in the division cycle but always at approximately the same time as initiation of chromosome replication. In cells growing with an interdivision time of 85 min, the F'lac episome replicated midway through the division cycle, whereas chromosome replication initiated at the start of the cycle. Measurements of absorbance at 450 nm per cell suggested that the F'lac replicated when the cells reached a mass which was a constant multiple of the number of episomes per cell at each growth rate. In contrast, the mass per cell at initiation of chromosome replication in cells with an 85-min interdivision time was significantly lower than this constant value. A possible explanation for the apparent coupling between F'lac replication and initiation of chromosome replication at the higher growth rates, and the lack of coupling at the lowest growth rate, is discussed.     

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.     

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.     

Replication control of autonomously replicating human sequences.

Three autonomously replicating plasmids carrying human genomic DNA and a vector derived from Epstein-Barr virus were studied by density labelling to determine the number of times per cell cycle these plasmids replicate in human cells. Each of the plasmids replicated semi-conservatively once per cell cycle. The results suggest that these human autonomously replicating sequences undergo replication following the same controls as chromosomal DNA and represent a good model system for studying chromosomal replication. We also determined the time within the S phase of the cell cycle that three of the plasmids replicate. Centromeric alpha sequences, which normally replicate late in S phase when in their chromosomal context, were found to replicate earlier when they mediate replication on an extrachromosomal vector. Reproducible patterns of replication within S phase were found for the plasmids, suggesting that the mechanism specifying time of replication may be subject to experimental analysis with this system.     

Primase p49 mRNA expression is serum stimulated but does not vary with the cell cycle.

Expression of the small-subunit p49 mRNA of primase, the enzyme that synthesizes oligoribonucleotides for initiation of DNA replication, was examined in mouse cells stimulated to proliferate by serum and in growing cells. The level of p49 mRNA increased approximately 10-fold after serum stimulation and preceded synthesis of DNA and histone H3 mRNA by several hours. Expression of p49 mRNA was not sensitive to inhibition by low concentrations of cycloheximide, which suggested that the increase in mRNA occurred before the restriction point control for cell cycle progression described for mammalian cells and was not under its control. p49 mRNA levels were not coupled to DNA synthesis, as observed for the replication-dependent histone genes, since hydroxyurea or aphidicolin had no effect on p49 mRNA levels when added before or during S phase. These inhibitors did have an effect, however, on the stability of p49 mRNA and increased the half-life from 3.5 h to about 20 h, which suggested an interdependence of p49 mRNA degradation and DNA synthesis. When growing cells were examined after separation by centrifugal elutriation, little difference was detected for p49 mRNA levels in different phases of the cell cycle. This was also observed when elutriated G1 cells were allowed to continue growth and then were blocked in M phase with colcemid. Only a small decrease in p49 mRNA occurred, whereas H3 mRNA rapidly decreased, when cells entered G2/M. These results indicate that the level of primase p49 mRNA is not cell cycle regulated but is present constitutively in proliferating cells.     

Bovine papilloma virus plasmids replicate randomly in mouse fibroblasts throughout S phase of the cell cycle

Bovine papilloma virus (BPV) replicates as a multicopy nuclear plasmid in mouse fibroblasts. Using fluorescence activated cell sorting and mitotic selection procedures, we show that the replication of BPV occurs throughout S phase of the cell cycle and that replication is confined to S phase. After one round of chromosomal DNA replication, almost one quarter of BPV plasmids have replicated more than once, while a similar number of plasmids have not replicated at all. While multiple forms of BPV exist in the cell, all forms show the same pattern of replication. These results are consistent with a model in which BPV plasmids are chosen at random for replication throughout, and only during, S phase and support the view that the completion of S phase is a specifically activated event in the cell cycle rather than simply the end of one round of chromosomal DNA replication.     

The configuration of DNA replication sites within the Trypanosoma brucei kinetoplast

The kinetoplast is a concatenated network of circular DNA molecules found in the mitochondrion of many trypanosomes. This mass of DNA is replicated in a discrete "S" phase in the cell cycle. We have tracked the incorporation of the thymidine analogue 5-bromodeoxyuridine into newly replicated DNA by immunofluorescence and novel immunogold labeling procedures. This has allowed the detection of particular sites of replicated DNA in the replicating and segregating kinetoplast. These studies provide a new method for observing kinetoplast DNA (kDNA) replication patterns at high resolution. The techniques reveal that initially the pattern of replicated DNA is antipodal and can be detected both on isolated complexes and in replicating kDNA in vivo. In Trypanosoma brucei the opposing edges of replicating kDNA never extend around the complete circumference of the network, as seen in other kinetoplastids. Furthermore, crescent-shaped labeling patterns are formed which give way to labeling of most of the replicating kDNA except the characteristic midzone. The configuration of these sites of replicated DNA molecules is different to previous studies on organisms such as Crithidia fasciculata, suggesting differences in the timing of replication of mini and maxicircles and/or organization of the replicative apparatus in the kinetoplast of the African trypanosome.     

AEC-Associated p63 Mutations Lead to Alternative Splicing/Protein Stabilization of p63 and Modulation of Notch Signaling

During the S phase of the cell cycle, the entire genome is replicated. There is a high level of orderliness to this process through the temporally and topologically coordinated activation of many replication origins situated along chromosomes. We investigated the program of replication from origins initiating in early S phase by labeling synchronized normal human fibroblasts (NHF1) with nucleotide analogs for various pulse times and measuring labeled tracks in combed DNA fibers. Our analysis showed that replication forks progress 9-35 kilobases from newly initiated origins, followed by a pause in synthesis before replication resumes. Pausing was not observed near origins that initiated in the middle of S phase. No evidence for pausing near origins was found at the beginning of the S phase in glioblastoma T98G cells. Treatment with the S phase checkpoint inhibitor caffeine abrogated pausing in NHF1 cells in early S phase. This suggests that pausing may comprise a novel aspect of the intra-S phase checkpoint pathway or a related new early S checkpoint. Further, it is possible that the loss of this regulatory process in cancer cells such as T98G could be a contributing factor in the genetic instability that typifies cancers.