Oxygen enhancement ratio as a function of dose and cell cycle phase for radiation-resistant and sensitive CHO cells

There is still controversy over whether the oxygen enhancement ratio (OER) varies as a function of dose and cell cycle phase. In the present study, the OER has been measured as a function of survival level and cell cycle phase using volume flow cell sorting. This method allows both the separation of cells in different stages of the cycle from an asynchronously growing population, and the precise plating of cells for accurate measurements at high survival levels. We have developed a cell suspension gassing and sampling system which maintained an oxygen tension less than 20 ppm throughout a series of sequential radiation doses. For both radiation-resistant cells (CHO-K1) and a radiation-sensitive clone (CHO-xrs6), we could separate relatively pure populations of G1-phase, G1/S-boundary, S-, and G2-phase cells. Each cell line showed a typical age response, with cells at the G1/S-phase boundary being 4 (CHO-K1) to 12 (CHO-xrs6) times more sensitive than cells in the late S phase. For both cell lines, G1-phase cells had an OER of 2.3-2.4, compared to an OER of 2.8-2.9 for S-phase and 2.6-2.7 for G2-phase cells. None of these age fractions showed a dependence of OER on survival level. Asynchronously growing cells or cells at the G1/S-phase boundary had an OER similar to that of G1-phase cells at high survival levels, but the OER increased with decreasing survival level to a value near that of S-phase cells. These results suggest that the decrease in OER at high survival levels for asynchronous cells may be due to differences in the OERs of the inherent cell age subpopulations. For cells in one cell cycle stage, oxygen appears to have a purely dose-modifying effect.     

An association between the radiation-induced arrest of G2-phase cells and low-dose hyper-radiosensitivity: a plausible underlying mechanism?

The survival of asynchronous and highly enriched G1-, S- and G2-phase populations of Chinese hamster V79 cells was measured after irradiation with 60Co gamma rays (0.1-10 Gy) using a precise flow cytometry-based clonogenic survival assay. The high-dose survival responses demonstrated a conventional relationship, with G2-phase cells being the most radiosensitive and S-phase cells the most radioresistant. Below 1 Gy, distinct low-dose hyper-radiosensitivity (HRS) responses were observed for the asynchronous and G2-phase enriched cell populations, with no evidence of HRS in the G1- and S-phase populations. Modeling supports the conclusion that HRS in asynchronous V79 populations is explained entirely by the HRS response of G2-phase cells. An association was discovered between the occurrence of HRS and the induction of a novel G2-phase arrest checkpoint that is specific for cells that are in the G2 phase of the cell cycle at the time of irradiation. Human T98G cells and hamster V79 cells, which both exhibit HRS in asynchronous cultures, failed to arrest the entry into mitosis of damaged G2-phase cells at doses less than 30 cGy, as determined by the flow cytometric assessment of the phosphorylation of histone H3, an established indicator of mitosis. In contrast, human U373 cells that do not show HRS induced this G2-phase checkpoint in a dose-independent manner. These data suggest that HRS may be a consequence of radiation-damaged G2-phase cells prematurely entering mitosis.     

Effect of methotrexate on the leukemic cell cycle in mouse ascitic leukemia L1210]

In cells of L1210 ascite leukemia cells, methotrexate inhibited H3-thymidine incorporation, blocked shortly (during 4 hours) the G1 leads to S transition, and did not affect cells in G2-phase or in the late S phase. Almost half a cell population was degenerated and cells in S- and G1-phases were affected in equal proportion. This may suggest that methotrexate is not S-phase specific for cells of leukemia L1210. A simultaneous administration of vinblastine increases the antitumour effect of methotrexate. Cells in G2-phase constitute, presumably, a significant proportion of cells recovered after methotrexate administration. A comparison of the data obtained with literature evidence shows that in the sensitive (leukemia L1210) and resistant (acute mieloid leukemia of man) forms of leukemia, methotrexate affects cells that are in S-phase, whereas cells being in G1-phase are affected only when the sensitive tumours are treated.     

Flow cytometric detection of mitotic cells using the bromodeoxyuridine/DNA technique in combination with 90 degrees and forward scatter measurements

Mitotic cells could be well discriminated from the cells in the G1-, S- and G2-phases of the cell cycle using pulse labeling of S-phase cells with bromodeoxy-uridine (BrdUrd) and staining of the cells for incorporated BrdUrd and total DNA content. Unlabeled G2- and M-phase cells could be measured as two separate peaks according to propidium iodide fluorescence. M-phase cells showed lower propidium iodide fluorescence emission compared to G2-phase cells. The fluorescence difference of M- and G2-phase cells was caused by the different thermal denaturation of their DNA. Best separation of M- and G2-phase cells was obtained after 30-50 min heat treatment at 95 degrees C. Mitotic index could be measured if no unlabeled S-phase cells were present in the cell culture. With additional measurements of 90 degree scatter and/or forward scatter signals, mitotic cells could be clearly discriminated from both unlabeled G2- and S-phase cells. The correct discrimination (about 99%) of mitotic cells from interphase cells was verified by visual analysis of the nuclear morphology after selective sorting. Unlabeled and labeled mitotic cells could be observed as pulse-labeled cells progressed through the cell cycle. We conclude that this modified BrdUrd/DNA technique using prolonged thermal denaturation and the simultaneous measurement of scatter signals may offer additional information especially in the presence of BrdUrd-unlabeled S-phase cells.     

The effect of picolinic acid and iron ions on the proliferation of SPEV cells

The effect of picolinic acid (PA) on SPEV cell proliferation is found to be different from that on normal and virus transformed NRC cells, and on spontaneously transformed CHO cells. It is shown that SPEV cells are arrested by PA at the end of G1-phase and at the beginning of S-phase and probably in G2-phase of the cell cycle. Ferrous ions remove the G1/S block induced by PA to permit the cell transfer through S-phase. On the one hand, PA chelates ferrous ions from the cells, and on the other one it inhibits the replicative DNA synthesis. It can be suggested that PA may arrest the SPEV cell growth affecting the iron-depend stable radical formation which is introduced into the active centre of ribonucleotiDE reduCTase. This results in the lower enzyme activity.     

Cell cycle kinetic measurements in an irradiated rat rhabdomyosarcoma using a monoclonal antibody to bromodeoxyuridine

Cell cycle kinetics after X-irradiation were studied in a solid rat rhabdomyosarcoma using a monoclonal antibody to bromodeoxyuridine (BrdUrd) in cells in which the DNA was labeled by BrdUrd. It could be shown that this tumor was composed of about 80% diploid host cells, and only 20% of the cells in the dissociated tumor were actually tetraploid tumor cells. When rats were injected intraperitoneally with BrdUrd to label S-phase cells in the tumor, only a fraction of both types of cells became labeled with BrdUrd during S-phase, even 24 h after injection. The diploid BrdUrd-labeled cells progressed rapidly into cycle; 4 h after injection of BrdUrd, labeled diploid G1-phase cells could be observed. Only 25% of the tetraploid S-phase cells could be labeled by a single injection of BrdUrd (160 mg/kg body weight). These labeled tetraploid cells progressed through the cell cycle with similar velocities as did labeled diploid cells. Using a "Mini Osmotic Pump" containing bromodeoxycytidine (BrdCyd) at high concentration (0.3 mol/L) that released BrdCyd continuously into the organism where it was converted to BrdUrd, it could be shown that after 2 days about 60% of cells in S-phase and 70% of cells in G2-phase were labeled. The fraction of labeled G2-phase cells in irradiated tumors (D = 10 and 20 Gy) was enhanced between 10 and 50 h after irradiation due to a radiation-induced G2 block in cycling tetraploid tumor cells.(ABSTRACT TRUNCATED AT 250 WORDS)     

Amiloride added together with bumetanide completely blocks mouse 3T3-cell exit from G0/G1-phase and entry into S-phase.

In this study we tested the hypothesis that stimulation of univalent-cation fluxes which follow the addition of growth factors are required for cell transition through the G1-phase of the cell cycle. The effect of two drugs, amiloride and bumetanide, were tested on exit of BALB/c 3T3 cells from G0/G1-phase and entry into S-phase (DNA synthesis). Amiloride, an inhibitor of the Na+/H+ antiport, only partially inhibited DNA synthesis induced by serum. Bumetanide, an inhibitor of the Na+/K+ co-transport, only slightly suppressed DNA synthesis by itself, but when added together with amiloride completely blocked cell transition through G1 and entry into S-phase. Similar inhibitory effects of the two drugs were found on the induction of ornithine decarboxylase (ODC) (a marker of mid-G1-phase) in synchronized cells stimulated by either partially purified fibroblast growth factor (FGF) or serum. To test this hypothesis further, cells arrested in G0/G1 were stimulated by serum, insulin or FGF. All induced similar elevations of cellular K+ content during the early G1-phase of the cell cycle. However, serum and FGF, but not insulin, released the cells from the G0/G1 arrest, as measured by ODC enzyme induction. This result implies that the increase in cellular K+ content may be necessary but not sufficient for induction of early events during the G1-phase. The synergistic inhibitory effects of amiloride and bumetanide on the two activities stimulated by serum growth factors, namely ODC induction (mid-G1) and thymidine incorporation into DNA (S-phase), suggested that the amiloride-sensitive Na+/H+ antiport system together with the bumetanide-sensitive Na+/K+ transporter play a role in the mitogenic signal.     

Requirement for phosphatidylinositol-3 kinase activity during progression through S-phase and entry into mitosis

Phosphatidylinositol-3 kinase (PI3K) proteins are important regulators of cell survival and proliferation. PI3K-dependent signalling regulates cell proliferation by promoting G1- to S-phase progression during the cell cycle. However, a definitive role for PI3K at other times during the cell cycle is less clear. In these studies, we provide evidence that PI3K activity is required during DNA synthesis (S-phase) and G2-phase of the cell cycle. Inhibition of PI3K with LY294002 at the onset of S-phase caused a 4- to 5-h delay in progression through G2/M. LY294002 treatment at the end of S-phase caused an approximate 2-h delay in progression through G2/M, indicating that PI3K activity functions for both S- and G2-phase progression. The expression of constitutively activated Akt partially reversed the inhibitory effects of LY294002 on mitotic entry, which demonstrated that Akt was one PI3K target that was required during G2/M transitions. Inhibition of PI3K resulted in enhanced susceptibility of G2/M synchronized cells to undergo apoptosis in response to DNA damage as compared to asynchronous cells. Thus, similar to its role in promoting cell survival and cell cycle transitions from G1 to S phase, PI3K activity appears to promote entry into mitosis and protect against cell death during S- and G2-phase progression.     

The blocking of the proliferation of the human endothelial cells in culture by beta-irradiation from internal and external sources of the radiation. S-block is induced by the 3H2O beta-particles

Recently we shown that low doses (0.12-0.46 Gy) of (methyl-3H)-thymidine incorporated into human endothelial cells induce the accumulation cells in G2-phase of the cell cycle. The temperate doses of (1-6 Gy) gamma-rays 137Cs were less effective in the induction of the G2-block estimated by flow cytometry analysis of DNA content and in the induction of the chromosome aberrations (bridges and fragments in anaphase). The aim of this study was the comparative investigation of efficiency of beta-rays emitted 3H from 3H-thymidine and 3H2O by several of the cellular parameters. Here we shown that at the equal conditions of the incubation of the cells in medium with 3H2O induced the accumulation cells in S-phase without decreasing of the mitotic activity and without increasing of the chromosome aberrations level. Unlike from 3H2O the incubation of the cells with 3H-thymidine induced the accumulation cells in G2-phase with decrease of the mitotic activity and with increase of the chromosome aberrations level. Concurrent treatment cells with 3H-thymidine and thymidine abrogate these cellular effects of the 3H-thymidine. Inhibitor ATM-kinase caffeine abrogate as G2-block as S-phase block. These results suggest that the low-dose beta-radiation activates S-phase and G2-phase checkpoints requiring ATM-mediated signal transduction pathway. The factors, which impact on the efficiency of the internal and of the external sources of the irradiation, depend on theirs disposition in relation to radiosensitive target--DNA was discussed.     

An immunological approach to enrich a mitotic stimulator and to reveal G2-phase-specific proteins in Physarum polycephalum

Purified antibodies from an antiserum against S-phase proteins of the myxomycete Physarum polycephalum were attached to protein-A-Sepharose CL-4B. A late G2-phase extract that contained a mitosis-stimulating protein was applied to this immunoadsorbent, and the mitosis-stimulating protein was enriched by a factor of ten. This protein, which is present in the cell in low amounts, is synthesized in late G2 phase and obviously degraded in a later stage of the cycle. Immunoadsorption of a G2-phase extract with anti-S-antibodies decreased the 700 main proteins to 20 as demonstrated by two-dimensional gel electrophoresis. No difference in protein pattern could be observed on two-dimensional gels between S-phase and G2-phase extracts before and after immunoadsorption with anti-S-antibodies. This indicates that there are no G2-phase-specific proteins among the 700 most abundant proteins of Physarum polycephalum.     

Mcm2, but not RPA, is a component of the mammalian early G1-phase prereplication complex.

Previous experiments in Xenopus egg extracts identified what appeared to be two independently assembled prereplication complexes (pre-RCs) for DNA replication: the stepwise assembly of ORC, Cdc6, and Mcm onto chromatin, and the FFA-1-mediated recruitment of RPA into foci on chromatin. We have investigated whether both of these pre-RCs can be detected in Chinese hamster ovary (CHO) cells. Early- and late-replicating chromosomal domains were pulse-labeled with halogenated nucleotides and prelabeled cells were synchronized at various times during the following G1-phase. The recruitment of Mcm2 and RPA to these domains was examined in relation to the formation of a nuclear envelope, specification of the dihydrofolate reductase (DHFR) replication origin and entry into S-phase. Mcm2 was loaded gradually and cumulatively onto both early- and late-replicating chromatin from late telophase throughout G1-phase. During S-phase, detectable Mcm2 was rapidly excluded from PCNA-containing active replication forks. By contrast, detergent-resistant RPA foci were undetectable until the onset of S-phase, when RPA joined only the earliest-firing replicons. During S-phase, RPA was present with PCNA specifically at active replication forks. Together, our data are consistent with a role for Mcm proteins, but not RPA, in the formation of mammalian pre-RCs during early G1-phase.     

Heat production of mammalian cells at different cell-cycle phases

1. 1.|Heat production of Reuber H35 rat hepatoma cells and murine C1300 neuroblastoma cells at different stages of the cell cycle were measured microcalorimetrically.

2. 2.|Reuber H35 monolayer cultures of G1-phase cells and cells in S-phase were trypsinized, reincubated in suspension culture and immediately used for microcalorimetric measurements. There was a remrkable difference in the heat evolution of H35-cells in suspension derived from a monolayer culture of G1-phase cells and that of cells in S-phase of the cell cycle. Heat production of G1-cells was relatively continuous during the experiment, in contrast to S-phase cells that showed a decrease in heat production after an initial maximum.

3. 3.|Neuroblastoma cells synchronized by mitotic shake-off and cultured in suspension progressed through their cell cycle. They showed maximal heat production shortly before and durign mitosis.

The effect of bleomycin on rapidly proliferating epidermis. A comparative investigation using micro-flow fluorometry, H3Tdr incorporation and a stathmokinetic method (colcemid).

At different time intervals after injection of Bleomycin (BLM) th effect on several kinetic parameters of the hairless mouse epidermis stimulated to proliferate by previous adhesive tape stripping was measured. Micro-flow fluorometry was used to determine the relative number of cells in the various phases of the cell cycle (G1, S and G2). Tritiated thymidine was used to determine labelling indices and grain counts. Colcemid was used to observe the mitotic rate. An initial decrease followed by a subsequent significant increase compared to the non-BLM-treated controls was observed in all parameters studied except the mitotic rate, which remained lower than in the control animals during all 48 hours. The transit time of the cells through the S-phase was initially slightly prolonged, but thereafter it seemed to be shorter than that of the controls. BLM seems to provoke a partial blocking of cells in the G1 phase. When the block is released, a greater number of cells pass through the S phase in partial synchrony at a higher than normal speed. BLM induced a low mitotic rate which remained below the level of that of the normal animals after stripping, even though there obviously was a considerably higher influx of cells from the S phase to the G2 phase. This resulted in a subsequent accumulation of cells in the G2-phase. Thus, BLM has also a blocking effect on the G2-M boundary of the cell cycle. This inhibitory effect of BLM on the mitotic rate was shown to be independent of the effect of BLM on the DNA synthesis. BLM therefore seems to have complex influence on epidermal cell kinetics in vivo. Cells in G1-phase are partially and transiently blocked, but this block is soon released. These cells thereafter pass through the S-phase and pile up in the G2-phase, because BLM also blocks the passage of cells from the G2-phase to mitosis. The overall reduction in cell proliferation seen after BLM in vivo seems mainly to be due to the effect on the G2-M boundray of the cell cycle.     

Okadaic Acid Blocks PDGF-Induced Proliferation of AKR-2B Fibroblasts at the Transition from G1- to S-Phase

Okadaic acid (OA) at 100 ng/ml completely inhibited platelet-derived growth factor (PDGF)-BB-induced DNA synthesis but had no effect on early signals, i.e., PDGF receptor autophosphorylation or stimulation of inositolphosphate turnover. A detailed analysis using synchronized cells showed that OA acts at the transition from G1-phase to S-phase. These observations were confirmed by flow cytometric DNA analysis of asynchronously grown cells. Here cells were specifically arrested in the G1-phase.     

Basal-cell subpopulations and cell-cycle kinetics in human epidermal explant cultures

Cultured human epidermal cells were studied by cell sorting and autoradiography after different 3H-thymidine (3H-dThd)-labelling procedures and after labelling with DNA precursors that are incorporated via salvage or de novo pathways. It was shown that 3H-dThd incorporation was the best measure of the rate of DNA replication. Dose-response experiments with pulse and continuous labelling revealed that all S- and G2-phase cells were cycling, whereas some 20% of the cells stayed in G1-phase for long periods of time. Most, if not all of these cells were probably non-proliferating differentiated keratinocytes. At least two subpopulations of S-phase cells could be discriminated on the basis of the rate of incorporation of DNA precursors. The difference in precursor incorporation did not seem to be caused by differences in nucleotide metabolism but rather to reflect true differences in the rate of DNA replication. Continuous labelling experiments showed that these subpopulations also were apparent in the G1- and G2-phases. Studies of the grain-count distribution revealed that cells that appeared to move rapidly through the S-phase moved slowly through the G2-phase, and vice versa. Cells stained with acridine orange were subjected to a two-parameter analysis in the cell sorter by simultaneous measurement of the DNA and RNA fluorescence. Autoradiography of sorted cells revealed that, on average, cells with low RNA contents incorporated 3H-dThd at a higher rate than cells with high RNA contents.     

Transformation abrogates an early G1-phase arrest point required for specification of the Chinese hamster DHFR replication origin.

The origin decision point (ODP) was originally identified as a distinct point during G1-phase when Chinese hamster ovary (CHO) cell nuclei experience a transition that is required for specific recognition of the dihydrofolate reductase (DHFR) origin locus by Xenopus egg extracts. Passage of cells through the ODP requires a mitogen-independent protein kinase that is activated prior to restriction point control. Here we show that inhibition of an early G1-phase protein kinase pathway by the addition of 2-aminopurine (2-AP) prior to the ODP arrests CHO cells in G1-phase. Transformation with simian virus 40 (SV40) abrogated this arrest point, resulting in the entry of cultured cells into S-phase in the presence of 2-AP and a disruption of the normal pattern of initiation sites at the DHFR locus. Cells treated with 2-AP after the ODP initiated replication specifically within the DHFR origin locus. Transient exposure of transformed cells to 2-AP during the ODP transition also disrupted origin choice, whereas non-transformed cells arrested in G1-phase and then passed through a delayed ODP after removal of 2-AP from the medium. We conclude that mammalian cells have many potential sites at which they can initiate replication. Normally, events occurring during the early G1-phase ODP transition determine which of these sites will be the preferred initiation site. However, if chromatin is exposed to S-phase-promoting factors prior to this transition, mammalian cells, like Xenopus and Drosophila embryos, can initiate replication without origin specification.     

Cell cycle specific plasmid DNA replication in the nuclear extract of Saccharomyces cerevisiae: modulation by replication protein A and proliferating cell nuclear antigen

Plasmid DNA replication in nuclear extracts of Saccharomyces cerevisiae in vitro has been shown to be S-phase specific, similar to that observed in vivo. We report here a reconstituted in vitro system with partially purified replication proteins, purified replication protein A (RPA), and recombinant proliferating cell nuclear antigen (PCNA). Nuclear extracts from S-phase, G(1)-phase, and unsynchronized yeast cells were fractionated by phosphocellulose chromatography. Protein fraction (polymerase fraction) enriched with replication proteins, including DNA polymerases (alpha, delta, etc.), was isolated, which was not capable of in vitro replication of supercoiled plasmid DNA. However, when purified yeast RPA and recombinant PCNA together were added to the polymerase fraction obtained from S-phase synchronized cells, in vitro plasmid DNA replication was restored. In vitro plasmid DNA replication with polymerase fractions from unsynchronized and G(1)-phase cells could not be reconstituted upon addition of purified RPA and PCNA. RPA and PCNA isolated from various phases of the cell cycle complemented the S-phase polymerase pool to the same extent. Reconstituted systems with the S-phase polymerase pool, complemented with either the RPA- and PCNA-containing fraction or purified RPA and recombinant PCNA together, were able to produce replication intermediates (ranging in size from 50 to 1500 bp) similar to that observed with the S-phase nuclear extract. Results presented here demonstrate that both RPA and PCNA are cell cycle-independent in their ability to stimulate in vitro plasmid DNA replication, whereas replication factors in the polymerase fractions are strictly S-phase dependent.     

Cell cycle-dependent effects of wortmannin on radiation survival and mutation

Wortmannin, a known radiation sensitizer, has been used in experiments with synchronized cells to compare its effect on radiation survival and mutation induction within the cell cycle. PL61 cells (CHO cells with an inactivated HPRT gene containing a single active copy of a bacterial gpt gene) were synchronized by mitotic selection. Wortmannin administered before gamma irradiation caused a greater sensitization in G(1)-phase cells relative to late S/G(2)-phase cells. Preferential radiosensitization of G(1)-phase cells by wortmannin sets a limit to the proposed use of wortmannin in radiation therapy, since, in contrast to normal tissues, tumors usually have high proportions of S-phase cells. Wortmannin increased mutation frequencies in both G(1)- and S/G(2)-phase cells. Interestingly, relative increases in radiation-induced mutations in G(1) and S/G(2) phases were comparable. The results are discussed in terms of the contributions of different repair modes in the production of mutations.     

Characterization of adriamycin-induced G2 arrest and its abrogation by caffeine in FL-amnion cells with or without p53

We investigated the effect of Adriamycin on FL-amnion (FL) cells. After treatment with the drug, the cells arrested at G2, but we did not detect an increase in the p21 levels. We established a p53-deficient derivative of these cells, in which G2 arrest also occurred after treatment with Adriamycin, suggesting that the arrest we observed in these cells is independent of the p53 pathway. Low doses of Adriamycin (100-200 ng/ml) induced G2 arrest, while late S-phase arrest was observed at high doses (500-1000 ng/ml) in both FL and p53-deficient FL cells. Accumulation of cyclin B1 was detected only in cells arrested at G2, and not in those arrested at S phase, suggesting that the S-phase checkpoint functioned efficiently even in p53-deficient FL cells. In both cell lines, caffeine-induced activation of CDC2 kinase was detected only in cells arrested at G2 and CDC2 kinase-activated cells died exhibiting features of apoptosis. CDC2 kinase activation was inhibited by cycloheximide. Furthermore, cycloheximide inhibited activation of CDK2:cyclin A, which normally precedes CDC2 kinase activation in caffeine-treated cells. These results suggest that p53 and p21 do not have special roles in the S- and G2-phase checkpoints and that CDK2:cyclin A could be the target of the G2-phase DNA damage checkpoint.     

Mechanisms of 2''-deoxyguanosine toxicity in mouse T-lymphoma cells with purine nucleoside phosphorylase deficiency and resistance to inhibition of ribonucleotide reductase by dGTP.

Purine nucleoside phosphorylase (PNP; EC 2.4.2.1) deficiency is thought to cause T-lymphocyte depletion by accumulation of dG and dGTP, resulting in feedback inhibition of ribonucleotide reductase (RR; EC 1.17.4.1) and hence DNA synthesis. To test for additional toxic mechanisms of dG, we selected a double mutant of the mouse T-lymphoma S-49 cell line, dGuo-L, which is deficient in PNP and partially resistant to dGTP feedback inhibition of RR. The effects of dG on dGuo-L cells (concn. causing 50% inhibition, IC50 = 150 microM) were compared with those on the wild-type cells (IC50 = 30 microM) and the NSU-1 mutant with PNP deficiency only (IC50 = 15 microM). Fluorescence flow cytometry showed that equitoxic dG concentrations arrested wild-type and NSU-1 cells at the G1-S interface while allowing continued DNA synthesis in the S-phase, whereas the double mutant dGuo-L cells progressed through the cell cycle normally. dGuo-L cells accumulated high levels of dGTP in G1-phase, but not in S-phase cells, because of the utilization of dGTP for DNA synthesis and limited capacity to synthesize dGTP from dG. These results support the hypothesis that dG/dGTP toxicity occurs in the G1-phase or at the G1-S interface. Failure of dG to arrest the double mutant dGuo-L cells at the G1-S interface allows these cells to escape into S-phase, with an accompanying drop in dGTP levels. Thus the partial resistance of dGuo-L cells to dG toxicity may result from their shorter residence time in G1, allowing them to sustain higher dGTP levels. Hence RR inhibition by dGuo may not be the primary toxic mechanism in S-49 cells; rather, it may serve as an accessory event in dG toxicity by keeping the cells in the sensitive phase of the cell cycle. Among the possible targets of dG toxicity is RNA synthesis, which was inhibited at an early stage in dGuo-L cells.