SEPARATION OF NUCLEI REPRESENTING DIFFERENT PHASES OF THE GROWTH CYCLE FROM UNSYNCHRONIZED MAMMALIAN CELL CULTURES

Nuclei have been isolated from unsynchronized cultures of Chinese hamster fibroblasts after varying intervals of growth following the incorporation of thymidine ^-3H for 20 min. These nuclei were fractionated by unit gravity sedimentation in a stabilizing density gradient of sucrose, and fractions were analyzed for the concentration of nuclei, DNA, and radioactivity. A more rapidly sedimenting population of nuclei in the G₂ phase of the cell cycle was separated from a group of nuclei in the G₁ phase, and nuclei in progressive stages of DNA synthesis (S phase) were distributed between these two regions. The fractionation of intact cells by sedimentation according to their position in the cell cycle was found to be less satisfactory than the corresponding separation of nuclei. This probably results from the continuous accumulation of mass within individual cells throughout the entire cell cycle, whereas most of the mass of a nucleus is replicated during a relatively narrow interval of the total cell cycle.     

Progressive Increase In Polyamine Levels In 9l Cells in vitro During the Cell Cycle: Comparison Between Cells Isolated By Centrifugal Elutriation and Cells Grown In Synchrony

Centrifugal elutriation was used to separate 9L rat brain tumour cells into fractions enriched in the G₁, S, or G₂/M phases of the cell cycle. Cells enriched in early G₁, phase were recultured, grown in synchrony, and harvested periodically for analysis of their DNA distribution and polyamine content. Mathematical analysis of the DNA distributions indicated that excellent synchrony was obtained with low dissersion throughout the cell cycle. Polyamine accumulation began at the time of seeding, and intracellular levels of putrescine, spermidine, and spermine increased continuously during the cell cycle. In cells in the G₂/M phase of the cell cycle, putrescine and spermidine levels were twice as high as in cells in the G₁, phase. DNA distribution and polyamine levels were also analysed in cells taken directly from the various elutriation fractions enriched in G₁, S, or G₂/M. Because we did not obtain pure S or G₂/M populations by elutriation or by harvesting synchronized cells, a mathematical procedure—which assumed that the measured polyamine levels for any population were linearly related to the fraction of cells in the G₁, S, and G₂/M phases times the polyamine levels in these phases and that polyamine levels did not vary within these phases—was used to estimate ‘true’ phase-specific polyamine levels (levels to be expected if perfect synchrony were achieved). Estimated ‘true’ phase-specific polyamine levels calculated from the data obtained from cells either sorted by elutriation or obtained from synchronously growing cultures were very similar.     

Expression of the p12 subunit of human DNA polymerase δ (Pol δ), CDK inhibitor p21WAF1, Cdt1, cyclin A,PCNA and Ki-67 in relation to DNA replication in individual cells

We recently reported that the p12 subunit of human DNA polymerase δ (Pol δ4) is degraded by CRL4^Cdt2 which regulates the licensing factor Cdt1 and p21^WAF1 during the G₁ to S transition. Presently, we performed multiparameter laser scanning cytometric analyses of changes in levels of p12, Cdt1 and p21^WAF1, detected immunocytochemically in individual cells, vis-à-vis the initiation and completion of DNA replication. The latter was assessed by pulse-labeling A549 cells with the DNA precursor ethynyl-2′-deoxyribose (EdU). The loss of p12 preceded the initiation of DNA replication and essentially all cells incorporating EdU were p12 negative. Completion of DNA replication and transition to G₂ phase coincided with the re-appearance and rapid rise of p12 levels. Similar to p12 a decline of p21^WAF1 and Cdt1 was seen at the end of G₁ phase and all DNA replicating cells were p21^WAF1 and Cdt1 negative. The loss of p21^WAF1 preceded that of Cdt1 and p12 and the disappearance of the latter coincided with the onset of DNA replication. Loss of p12 leads to conversion of Pol δ4 to its trimeric form, Pol δ3, so that the results provide strong support to the notion that Pol δ3 is engaged in DNA replication during unperturbed progression through the S phase of cell cycle. Also assessed was a correlation between EdU incorporation, likely reflecting the rate of DNA replication in individual cells, and the level of expression of positive biomarkers of replication cyclin A, PCNA and Ki-67 in these cells. Of interest was the observation of stronger correlation between EdU incorporation and expression of PCNA (r = 0.73) than expression of cyclin A (r = 0.47) or Ki-67 (r = 0.47).     

Cell cycles in embryos of the silkworm,Bombyx mori: G2-arrest at diapause stage

Summary In the silkworm, Bombyx mori, diapause occurs at a specific embryonic stage, i.e. after formation of the germ band with cephalic lobes and telson and sequential mesoderm segmentation. As long as the eggs are incubated at 25° C, cell divisions and morphological development of the embryos cease. To examine changes in percentage of embryonic cells in the G₁, S and G₂ phases during embryogenesis, nuclear fractions were isolated from embryos, stained with propidium iodide and then subjected to flow cytometric analysis. The percentages of embryonic cells in G₁, S and G₂ were 10, 35 and 55%, respectively, at the stage of formation of cephalic lobes, whilst 98% of cells were in G₂ at diapause stage. After termination of diapause by acclimation at 5° C or by a combination of chilling and HCl, cell division resumed in the embryos. During this period, the cells rapidly entered S phase through G₁ from G₂, suggesting that their G₁ phase was short. In eggs in which diapause was averted by HCl-treatment after incubation at 25° C for 20 h after oviposition, embryonic development proceeded continuously for 9.5 days at 25° C until hatching. Along with this development, the G₁ fraction increased to levels of about 90%. These results indicate that embryonic cells are arrested in G₂ at diapause and suggest that, concomitant with further embryonic development, cell cycles become slower in proportion to an increasing length of G₁. Finally, most of the cells may be arrested in G₁, while there is only a small fraction of cells continuously cycling. Offprint requests to: T. Yaginuma     

In vitro DNA synthesis as indicator of mammary epithelial cell division: [14C]thymidine uptake versus flow cytometry cell cycle analysis

Summary Mammary and adipose explants from eight mid-lactation Holstein cows were co-cultured for 24 h in the presence or absence of liver explants, 1 μg/ml pituitary bovine somatotrophin, or 100 ng/ml insulinlike growth factor-I. Liver explants in the media significantly depressed DNA and protein synthesis by mammary tissue as measured by [¹⁴C]-thymidine and amino acid incorporation. As measured by flow cytometry, the concentration of DNA in the G₀G₁ and G₂M cells and the percentage of cells in the G₀G₁ population of mammary tissue was also significantly depressed by liver tissue. Changes in the percentage of cells in the S and G₂M phases were not significant. Insulinlike growth factor-I in the presence of liver explants depressed protein synthesis, thymidine incorporation, and the concentration of DNA in the G₀G₁ and G₂M cells compared to control but did not affect the percentage of cells in the G₀G₁, S, or G₂M phases. Previously it was assumed that changes in [¹⁴C]thymidine incorporation indicated that changes in cell division were occurring. Flow cytometry revealed that changes in DNA content of mammary cells as a result of liver or hormonal stimulation were not due to changes in cell division. Indications are that differences in cellular DNA content result from changes in the rate of amplification of individual genes responsible for milk protein synthesis.     

CELL MITOTIC CYCLE SYNTHESIS OF NIL HAMSTER GLYCOLIPIDS INCLUDING THE FORSSMAN ANTIGEN

The synthesis of phospholipids and glycolipids during the cell mitotic cycle of an established hamster line, NIL, has been studied. Cells were synchronized with excess thymidine and mitotically harvested by shaking. Cells were radioactively labeled for 4 h with palmitate, glucosamine, or galactose. Lipids were analyzed by thin-layer chromatography. As cells progressed through the mitotic cycle, incorporation into phospholipids increased but the fraction represented by each remained constant. Similarly, ceramide monohexoside, dihexoside, and hematoside were labeled equally in all phases. Ceramide trihexoside and tetrahexoside were labeled only during G₁ and S. Ceramide pentahexoside (the Forssman antigen) shows density-dependent synthesis, accumulation, and reactivity. Ceramide pentahexoside was labeled during all phases of the mitotic cycle but the rate of incorporation decreased in S and G₂. The total amount of lipid assayed immunologically in cell extracts gradually increased. Exposure of the Forssman antigen in untreated or trypsin-treated cells was studied using binding of chemically labeled antiForssman antiserum. The amount of antigen detected in trypsinized cells increased during G₁ and early S but then remained constant. Mitotic cells exposed all detectable antigen. As cells progressed through the mitotic cycle, a large fraction of the Forssman antigen became cryptic.     

Expression of the mitochondrial genome in HeLa cells. XXI. Mitochondrial protein synthesis during the cell cycle

Chloramphenicol sensitive [³H]leucine incorporation into protein (due to mitochondrial protein synthesis) in synchronized HeLa cells has been found to continue throughout interphase, its rate per cell approximately doubling from the G₁ to the G₂ phase. This increase in the rate of [³H]leucine incorporation during the cycle does not seem to parallel closely the increase in cell mass. In fact, the observations made on cultures incubated at 34.5 °C, where the G₁ and S phases are better resolved than at 37 °C, indicate that the rate remains constant during the G₁ phase, and starts to accelerate with the onset of nuclear DNA synthesis. Correspondingly, on a per unit mass basis, there appears to be a slight decline in the rate of [³H]leucine incorporation into protein during the G₁ phase, which is compensated by an increase in the early S phase. No significant variations were observed in the mitochondrial leucine pool labeling during the cell cycle; therefore, the observed pattern of [³H]leucine incorporation into protein should reflect fairly accurately the behavior of mitochondrial protein synthesis. Evidence has been obtained indicating a depression in the rate of incorporation of [³H]leucine into protein in mitochondria of mitotic cells. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis analysis of the products of mitochondrial protein synthesis has not revealed any differences in the size distribution of the proteins synthesized in the various portions of the cell cycle.     

Autoradiographic studies on the incorporation of3H-amino acids into chromosomes during the mitotic cell cycle ofHaplopappus gracilis

The synthesis of chromosomal proteins and the incorporation of labelled proteins into chromosomes in the mitotic cell cycle ofHaplopappus gracilis, 2n=4, were traced autoradiographically with³H-arginine,³H-lysine, and³H-tryptophane. The duration of the mitotic cell cycle in the root tip cells was determined by³H-thymidine autoradiography and was measured to be 13.0 hr (G₁ 1.3 hr, S 6.5 hr, G₂ 3.8 hr and M 1.4 hr).³H-arginine labelled proteins which were synthesized at S and G₂ were found to be incorporated into chromosomes to a greater extent than proteins which were synthesized either at G₁, at the transition phase from late S to early G₂, or at the mitotic phase. Such varied incorporation was also found in³H-lysine labelled proteins, but not in³H-tryptophane labelled proteins. These findings indicate that the chromosomal proteins are synthesized mainly at S and G₂. Some of the³H-arginine labelled proteins which were synthesized during the first mitotic cell cycle, were found to be incorporated into the chromosomes of the second mitotic cell cycle. The incorporation of the proteins synthesized at one stage of the mitotic cell cycle was found to occur locally in some regions of the chromosomes, while the pattern of incorporation was observed to be similar between euchromatic and heterochromatic regions.     

DNA synthesis and cell cycle progression of synchronized L-cells after irradiation in various phases of the cell cycle

Summary The varying sensitivity to radiation in the different phases of the cell cycle was investigated using L-929 cells of the mouse. The cells were synchronized by mechanical selection of mitotic cells. The synchronous populations were X-irradiated with a single dose of 10 Gy in the middle of the G₁-phase, at the G₁/S-transition or in the middle of the S-phase, respectively. The radiation effect was determined in 2 h intervals a) by¹⁴C-TdR incorporation (IT) into the DNA, b) by autoradiography (AR), c) by flow cytometry (FCM). The incorporation rate decreased in all three cases, but the reasons appeared to be different, as can be derived from FCM and AR data: After irradiation in G₁, a fraction of cells was prevented from entering S-phase, after irradiation at G₁/S a proportion of cells was blocked in the S-phase, and after irradiation in S, DNA synthesis rate was reduced. As a consequence of these effects, the mean transition time through S-phase increased. The G₂ blocks, obtained after irradiation at the three stages of the cycle were also different: Cells irradiated in G₁ are partly released from the block after 10 h. Irradiation at G₁/S caused a persisting accumulation of 50% of the cells in G₂, and for irradiation in S more than 80% of the cells were arrested in G₂.     

CELL CYCLE-SPECIFIC CHANGES IN HISTONE PHOSPHORYLATION ASSOCIATED WITH CELL PROLIFERATION AND CHROMOSOME CONDENSATION

Preparative polyacrylamide gel electrophoresis was used to examine histone phosphorylation in synchronized Chinese hamster cells (line CHO). Results showed that histone f1 phosphorylation, absent in G₁-arrested and early G₁-traversing cells, commences 2 h before entry of traversing cells into the S phase. It is concluded that f1 phosphorylation is one of the earliest biochemical events associated with conversion of nonproliferating cells to proliferating cells occurring on old f1 before synthesis of new f1 during the S phase. Results also showed that f3 and a subfraction of f1 were rapidly phosphorylated only during the time when cells were crossing the G₂/M boundary and traversing prophase. Since these phosphorylation events do not occur in G₁, S, or G₂ and are reduced greatly in metaphase, it is concluded that these two specific phosphorylation events are involved with condensation of interphase chromatin into mitotic chromosomes. This conclusion is supported by loss of prelabeled ³²PO₄ from those specific histone fractions during transition of metaphase cells into interphase G₁ cells. A model of the relationship of histone phosphorylation to the cell cycle is presented which suggests involvement of f1 phosphorylation in chromatin structural changes associated with a continuous interphase "chromosome cycle" which culminates at mitosis with an f3 and f1 phosphorylation-mediated chromosome condensation.     

Gradient fractionation of cycling and resting cells monitored by BrdUrd incorporation

Summary A number of techniques are currently employed for the fractionation of heterogeneous cell populations or for the separation of cells in different phases of their cycle. With the development of osmotically inert colloidal silica particles media, density gradient centrifugation became an established method for the separation and purification of cells and subcellular particles. We have applied this technique to the separation of cycling from resting Friend erythroleukemia cells, to obtain purified populations for further biological assays. The flow cytometric analysis of DNA content of the different fractions obtained by the gradient and stained with Propidium lodide (PI), showed the S compartment highly concentrated in the 1.073/77g/ml interface, while the upper levels of the gradient were highly enriched of cells in G₁ phase. Moreover, the dual parameter analysis of DNA content by means of Bromodeoxyuridine (BrdUrd) incorporation and PI staining, showed that part of the cells in the 1.067/73 fraction represented the early S phase even if their DNA level, measured on the basis of PI fluorescence was within the diploid cell cluster. This method seems to be suitable to obtain pure cell fractions even when dealing with numerically large populations.     

Synchronization of 9L rat brain tumor cells by centrifugal elutriation

Asynchronous 9L cells were separated into relatively homogeneously-sized populations using centrifugal elutriation with both a conventional collection method and a long collection method. A substantial increase in the homogeneity of the volume distributions and in the degree of synchrony of the separated fractions was obtained using the long collection method. Autoradiographic data indicated that fractions containing ≥97% G₁ cells, ≥80% S cells, and 70–75% G₂ cells could be routinely recovered with this procedure. Recovery in these fractions varied from 5 to 8% of the total number of cells elutriated. The colony forming efficiency (CFE) of cells from fractions representing each phase of the cell cycle was a constant 60–70%, which was comparable to the 60–80% usually found for asynchronous 9L cells. The percentage of cells in the G₁, S, and G₂ phases in the elutriated fractions was more accurately determined from the volume distribution than from computer fits of the DNA histogram obtained from flow cytometry. In general, the degree of synchrony was related to the coefficient of variation (CV) of the volume distributions of the elutriated fractions. The CV was about 14% for all elutriated fractions. When the ≥97% G₁ population was allowed to progress to S and G₂, the CVs were about 17 and 20.2%, respectively. Thus, the best nonperturbing method for obtaining synchronous 9L cells in the S or G₂ phases was direct elutriation with the long collection method.     

THE SYNTHESIS OF PHOSPHOLIPIDS IN THE NUCLEUS AND NUCLEAR MEMBRANE OF SYNCHRONIZED HeLa CELLS

HeLa cells were synchronized by a double thymidine block and pulse labeled at different stages of the cell cycle with ³H-choline. The specific activity of phospholipids extracted from the cell, the nucleus and the nuclear membrane showed a progressive increase from S to G₁; the incorporation of choline into phospholipids of asynchronous cells showed a specific activity intermediate between the values of S and G₁ cells. Similar results were obtained when ³²phosphorus was used as a precursor instead of choline. Thin layer chromatographic analysis of phospholipids extracted from cells in S and from cells in G₁ failed to show any difference in the distribution of radioactivity among the various phospholipid classes. Choline uptake by HeLa cells in different phases of the cell cycle did not show significant variations. However, during the synchronization process, shortly after the addition of excess thymidine, an increased uptake of choline by cells and an increased incorporation of choline into phospholipids were found. The results indicate that some of the changes occurring in phospholipids synthesis may not be cell cycle dependent, but may be the effect of the synchronizing process.     

Kinetic Differences Between Fed and Starved Chinese Hamster Ovary Cells

When Chinese hamster (CHO-K1) cells are grown as monolayer cultures, they eventually reach a population-density plateau after which no net increase in cell numbers occurs. the kinetics of aged cells in nutritionally deprived (starved) or density-inhibited (fed) late plateau-phase cultures were studied by four methods: (i) Reproductive integrity and cell viability were monitored daily by clonogenic-cell assay and erythrosin-b dye-exclusion techniques. (ii) Mitotic frequencies of cells from 18 day old cultures were determined during regrowth by analysing time-lapse video microscope records of dividing cells. (iii) Tritiated-thymidine ([³H]TdR) auto-radiography was used to determine the fractions of DNA-synthesizing cells in cultures entering plateau phase and during regrowth after harvest. (iv) the rate of labelled nucleoside uptake and incorporation into DNA was measured using liquid scintillation or sodium iodide crystal counters after labelling with [³H]TdR or [¹²⁵]UdR. Non-cycling cells in starved cultures accumulate primarily as G₁, phase cells. Most cells not in G₁ phase had stopped in G₂, phase. Very few cells (< 2%) were found in S phase. In contrast, about half of the cells in periodically fed cultures were found to be in DNA-synthetic phase, and the percentage of these S phase cells fluctuated in a manner reflecting the frequency of medium replacement. Populations of both types of plateau-phase cultures demonstrate extremely coherent cyclic patterns of DNA synthesis upon harvest and reculturing. They retain this high degree of synchrony for more than three generations after the resumption of growth. From these data it is concluded that nutritionally deprived (starved) late plateau-phase cells generally stop in either G₁, or G₂, phase, whereas periodically fed late plateau-phase cultures contain a very large fraction of cycling cells. Populations of cells from these two types of non-expanding cultures are kinetically dissimilar, and should not be expected to respond to extracellular stimuli in the same manner.     

Ultrastructural localization of adenosine triphosphatase activity in HeLa cells at various stages of the cell cycle

Summary HeLa cells in a monolayer culture were synchronized to S, G₂ and mitotic phases by use of excess (2.5 mM) deoxythymidine double-block technique. The localizations of Ca⁺⁺-activated adenosine triphosphatase (ATPase) at different phases of the cell cycle were studied using light and electron-microscopic histochemical techniques, and microphotometric comparisons of the densities of reaction products. Enzyme reaction product was always localized in the endoplasmic reticulum, nuclear membrane, mitochondria and Golgi apparatus, but there were qualitative and quantitative differences related to the phases of the cell cycle. In S phase the activity was mainly concentrated in a perinuclear area of the cytoplasm whereas in G₂ and mitosis the activity was scattered throughout the cell. The total activity per cell was maximal in G₂, was less in S phase and least in mitosis. Activity in the mitochondria and endoplasmic reticulum was distinctly less in mitosis than in other phases of the cell cycle. The mitochondrial ATPase differed from the ATPase at other sites in ion dependence and sensitivity to oligomycin. The results suggest that there may be several distinct ATPases in proliferating cells.     

Cell cycle regulation during growth-dormancy cycles in pea axillary buds

Accumulation patterns of mRNAs corresponding to histones H2A and H4, ribosomal protein genes rpL27 and rpL34, MAP kinase, cdc2 kinase and cyclin B were analyzed during growth-dormancy cycles in pea (Pisum sativum cv. Alaska) axillary buds. The level of each of these mRNAs was low in dormant buds on intact plants, increased when buds were stimulated to grow by decapitating the terminal bud, decreased when buds ceased growing and became dormant, and then increased when buds began to grow again. Flow cytometry was used to determine nuclear DNA content during these developmental transitions. Dormant buds contain G₁ and G₂ nuclei (about 3:1 ratio), but only low levels of S phase nuclei. It is hypothesized that cells in dormant buds are arrested at three points in the cell cycle, in mid-G₁, at the G₁/S boundary and near the S/G₂ boundary. Based on the accumulation of histone H2A and H4 mRNAs, which are markers for S phase, cells arrested at the G₁/S boundary enter S within one hour of decaptitation. The presence of a cell population arrested in mid-G₁ is indicated by a second peak of histone mRNA accumulation 6 h after the first peak. Based on the accumulation of cyclin B mRNA, a marker for late G₂ and mitosis, cells arrested at G₁/S begin to divide between 12 and 18 h after decapitation. A small increase in the level of cyclin B mRNA at 6 h after decapitation may represent mitosis of the cells that had been arrested near the S/G₂ boundary. Accumulation of MAP kinase, cdc2 kinase, rpL27 and rpL34 mRNAs are correlated with cell proliferation but not with a particular phase of the cell cycle.     

Cell-cycle dependency of radiosensitivity and mutagenesis in fertilized egg cells of rice,Oryza sativa L.

Summary In order to examine changes in survival and mutation rates during a cell cycle in higher plant, fertilized egg cells of rice were irradiated with X-rays at 2 h intervals for the first 36 h after pollination, i.e., at different phases of the first and second cell cycles. The most sensitive phase in lethality was late G₁ to early S, followed by late G₂ to M, which were more sensitive than the other phases. In both M₁ and M₂ generations, sterile plants appeared most frequently when fertilized egg cells were irradiated at G₂ and M phases. Different kinds of mutated characters gave rise to the respective maximum mutation rates at different phases of a cell cycle: namely, albino and viridis were efficiently induced at early G₁, xantha at early S, short-culm mutant at mid G₂, heading-date mutant at M to early G₁. The present study suggests the possibility that the differential mutation spectrums concerning agronomic traits are obtained by selecting the time of irradiation after pollination.     

Tumor-specific cell-cycle decoy by Salmonella typhimurium A1-R combined with tumor-selective cell-cycle trap by methioninase overcome tumor intrinsic chemoresistance as visualized by FUCCI imaging

We previously reported real-time monitoring of cell cycle dynamics of cancer cells throughout a live tumor intravitally using a fluorescence ubiquitination cell cycle indicator (FUCCI). Approximately 90% of cancer cells in the center and 80% of total cells of an established tumor are in G₀/G₁ phase. Longitudinal real-time FUCCI imaging demonstrated that cytotoxic agents killed only proliferating cancer cells at the surface and, in contrast, and had little effect on the quiescent cancer cells. Resistant quiescent cancer cells restarted cycling after the cessation of chemotherapy. Thus cytotoxic chemotherapy which targets cells in S/G₂/M, is mostly ineffective on solid tumors, but causes toxic side effects on tissues with high fractions of cycling cells, such as hair follicles, bone marrow and the intestinal lining. We have termed this phenomenon tumor intrinsic chemoresistance (TIC). We previously demonstrated that tumor-targeting Salmonella typhimurium A1-R (S. typhimurium A1-R) decoyed quiescent cancer cells in tumors to cycle from G₀/G₁ to S/G₂/M demonstrated by FUCCI imaging. We have also previously shown that when cancer cells were treated with recombinant methioninase (rMETase), the cancer cells were selectively trapped in S/G₂, shown by cell sorting as well as by FUCCI. In the present study, we show that sequential treatment of FUCCI-expressing stomach cancer MKN45 in vivo with S. typhimurium A1-R to decoy quiescent cancer cells to cycle, with subsequent rMETase to selectively trap the decoyed cancer cells in S/G₂ phase, followed by cisplatinum (CDDP) or paclitaxel (PTX) chemotherapy to kill the decoyed and trapped cancer cells completely prevented or regressed tumor growth. These results demonstrate the effectiveness of the praradigm of “decoy, trap and shoot” chemotherapy.     

Modulation of G(2) arrest enhances cell death induced by the antitumor 1-nitroacridine derivative,Nitracrine

Nitracrine (Ledakrin) is an antitumor drug which is activated by cellular enzymes and binds covalently to DNA. Previous studies have shown that covalent binding and crosslinking of DNA is associated with the cytotoxic and antitumor activities of this compound. In this study, cell cycle perturbations, effects on DNA synthesis and the cell death process initiated by Nitracrine were studied in murine leukemia L1210 cells. We show that exposure of L1210 cells to Nitracrine at the IC₉₉ concentration delayed progression through the S phase and transiently arrested cells in G₂/M as found by flow cytometry. Higher drug concentration (2 × IC₉₉) inhibited cell cycle progression in the S phase and induced rapid cell death. Both studied concentrations of the drug produced different effects on DNA synthesis as determined by bromodeoxyuridine incorporation, with a delay in the S phase progression at EC₉₉ concentration and irreversible arrest in early S phase at the higher dose (2 × IC₉₉). At both concentrations of Nitracrine cell death occurred preferentially in the S phase as revealed by the TUNEL assay. When cells treated with the drug for 4 hours were post-incubated in the presence of 1 mM caffeine this led to rapid cell death and suppression of the G₂ arrest. This was associated with a about 10-fold increase in the cytotoxicity of Nitracrine. Similar effects were observed for another DNA crosslinking agent, cis-platinum, and to a lesser extent, for DNA topoisomerase I inhibitor, camptothecin. Together, our studies show that suppression of G₂ arrest induced by Nitracrine greatly enhances its cytotoxicity toward L1210 cells.