Effects of repair inhibition in the G1 phase of clastogen-treated human lymphocytes on the frequencies of chromosome-type and chromatid-type aberrations and sister-chromatid exchanges

It has been shown that certain types of DNA lesions induced by an S-dependent clastogen are converted to chromosome-type aberrations when their repair is inhibited in the G1 phase of the cell cycle. The purpose of the present study was to investigate which kinds of repair inhibitors have the ability to induce chromosome-type aberrations in cells having DNA lesions and which kinds of DNA lesions will be converted to chromosome-type aberrations when their repair is inhibited. For this purpose, human peripheral blood lymphocytes, which were treated with a clastogen in their G0 phase, were post-treated with one of several kinds of repair inhibitors in the G1 phase, and resulting frequencies of both chromosome-type and chromatid-type aberrations as well as of sister-chromatid exchanges (SCEs) were compared with those of the control cultures: chromatid-type aberrations and SCEs were adopted as cytogenetic indicators of lesions remaining in S and G2 phases. Chemicals used for the induction of DNA lesions were 4-nitroquinoline 1-oxide (4NQO), methyl methanesulfonate (MMS) and mitomycin C (MMC); inhibitors used were excess thymidine (dThd), caffeine, hydroxyurea (HU), 5-fluoro-2'-deoxyuridine (FdUrd), 1-beta-D-arabinofuranosylcytosine (ara C), 9-beta-D-arabinofuranosyladenine (ara A), 1-beta-D-arabinofuranosylthymine (ara T) and aphidicolin (APC). Induction of chromosome-type aberrations was observed in cells pretreated with 4NQO or MMS followed by ara C, ara A, ara T or APC, whereas other combinations of a clastogen and an inhibitor did not induce them. Among the inhibitors, ara C alone induced chromosome-type aberrations in cells without pretreatment. Chromatid-type aberrations were increased only in cells pretreated with MMC and their frequency was enhanced further by post-treatment with ara C. All of the clastogens used in the present experiments induced SCEs. Most inhibitors did not modify the SCE frequencies except for ara C which synergistically increased the frequency in MMC-treated cells. The present study offers further evidence that the lesions responsible for chromosome-type aberrations are those which are repaired quickly, and that they are converted to chromosome-type aberrations when repair by polymerase alpha is inhibited. The effects of ara C on MMC-induced lesions are considered residual effects of ara C treatment in the S or G2 phases rather than repair inhibition in the G1 phase.     

Cell cycle-related variations in UV damage and repair capacity in chinese hamster (CHO-K1) cells

UV damage to CHO cell DNA, measured by formation of thymine-containing dimers, increases from mitosis to early S phase. Computer simulation of UV absorption by the DNA of an idealized CHO cell at different stages in the cell cycle resembles the cycle dependence of UV damage. Incision at UV damage sites, measured by the accumulation of breaks in preexisting DNA during 30 minutes' post-irradiation incubation with the DNA synthesis inhibitors 1-β-D arabinofuranosylcytosine and hydroxyurea, increases from mitosis to interphase. Analysis of the dose dependence of DNA break accumulation indicates that both the affinity of the endonuclease for dimer sites and the maximum enzyme activity at saturating levels of dimers are significantly lower in mitosis than in interphase. The killing of CHO cells by UV is enhanced if repair is temporarily inhibited by ara C. The DNA gyrase inhibitor novobiocin prevents UV-induced incision.     

Elevation of dCTP pools in xeroderma pigmentosum variant human fibroblasts alters the effects of DNA repair arrest by arabinofuranosyl cytosine

DNA excision repair inhibition by arabinofuranosyl cytosine (ara-C) or by ara-C/hydroxyurea (HU) was measured in log phase and confluent cultures of normal and xeroderma pigmentosium (XP)-variant human fibroblasts following insult by ultraviolet (UV) light (20 J/m²). Repair inhibition was determined by measuring the accumulation of DNA single-strand breaks/10⁸ daltons following cell culture exposure to ara-C or ara-C/HU in a series of 3 hr. pulses up ro 24 hr. after UV insult. Both normal and XP-variant derived cells showed a wide range of sensitivity to ara-C in log phase cells (0.2–9.4 breaks/10⁸ daltons DNA), although strand break accumulation was constant for each specific cell line. The same cells were more sensitive to ara-C/HU with a 2–14 fold increase in DNA strand breaks depending upon the cell line assayed. In confluent cultures of normal cells, maximum sensitivity to ara-C and ara-C/HU was achieved with similar levels of repair inhibition observed (16.1 and 16.5 breaks/10⁸ daltons, respectively). The same level of repair inhibition was observed in confulent XP-variants receiving ara-C/HU, but was reduced by 62–68% in cells treated with ara-C alone. Ara-C repair arrest was more rapidly reversed by competing concentrations of exogenous deoxycytidine (dCyd) in XP-variant compared to normal cells, especially in confluent cell cultures. In ara-C/HU treated cells, the level of dCyd reversal was reduced in the XP-variant when compared to cells exposed to ara-C alone. However, the same addition of HU had relatively little effect on dCyd reversal in normal cells. The measurements of dNTP levels indicate an elevated level of intracellular deoxycytosine triphosphate in XP-variant vs normal cells. The implications of these results are discussed as they relate to possible excision repair anomalies in the XP-variant.Abbreviations ara-C arabinofuranosul cytosine - dCTP deoxycytosine triphosphate - dCyd deoxycytidine - dNTP deoxynucleoside triphosphate - dT thymidine - HU hydroxyurea - XP xeroderma pigmentosium This research was sponsored jointly by the National Cancer Institute under Interagency Agreement #40-5-63, and the Office of Health and Environment Research, U. S. Department of Energy, under Contract W-7405-eng-26 with the Union Carbide Corporation.     

The mode of action of 1-beta-D-arabinofuranosylcytosine in inhibiting DNA repair; new evidence using a sensitive assay for repair DNA synthesis and ligation in permeable cells

Mammalian cells permeabilised by treatment with saponin are capable of UV excision repair. We have developed an assay system which permits measurement of the later stages of repair, i.e. repair synthesis and ligation. Incomplete repair sites are accumulated in UV-irradiated cells by incubating them with DNA synthesis inhibitors hydroxyurea and aphidicolin. On removal of the inhibitors at the time of permeabilisation, these incomplete sites, detected as DNA breaks, are rapidly ligated in a reaction that requires deoxyribonucleoside triphosphates and is blocked by aphidicolin. Thus ligation is possible only after a significant amount of DNA synthesis. We have used the assay to clarify the mode of inhibition of DNA repair by 1-beta-D-arabinofuranosylcytosine (ara C), another DNA polymerase inhibitor. It is well known that incomplete repair sites accumulated in whole cells with ara C are ligated at a slow rate, if at all. The hypothesis that ara C blocks or reduces further polymerisation after its incorporation into repair patches is disproved by our demonstration that, in permeable cells, the accumulated DNA breaks are ligated very rapidly. The likely explanation of the action of ara C is that, once phosphorylated, it remains in the cell as ara CTP and continues to inhibit polymerisation through competition with dCTP; in permeable cells, it readily leaks out.     

A cell cycle-specific requirement for the XRCC1 BRCT II domain during mammalian DNA strand break repair

XRCC1 protein is essential for viability in mammals and is required for efficient DNA single-strand break repair and genetic stability following DNA base damage. We report here that XRCC1-dependent strand break repair in G(1) phase of the cell cycle is abolished by mutations created within the XRCC1 BRCT domain that interact with DNA ligase III. In contrast, XRCC1-dependent DNA strand break repair in S phase is largely unaffected by these mutations. These data describe a cell cycle-specific role for a BRCT domain, and we conclude that the XRCC1-DNA ligase III complex is required for DNA strand break repair in G(1) phase of the cell cycle but is dispensable for this process in S phase. The S-phase DNA repair process can remove both strand breaks induced in S phase and those that persist from G(1) and can in part compensate for lack of repair in G(1). This process correlates with the appearance of XRCC1 nuclear foci that colocalize with Rad51 and may thus function in concert with homologous recombination.     

Repair of cytokine-induced DNA damage in cultured rat islets of Langerhans

Treatment of cultured rat pancreatic islets of Langerhans with the combined cytokines interleukin-1beta (IL-1beta), interferon gamma (IFN gamma) and tumour necrosis factor alpha (TNF alpha) leads to DNA damage including strand breakage. We have investigated the nature of this damage and its repairability. When islets are further incubated for 4 h in fresh medium, the level of cytokine-induced strand breakage remains constant. If the nitric oxide synthase inhibitor N(G)-monomethyl-L-arginine (NMMA) is present during cytokine treatment, then strand breakage is prevented. If NMMA is added following, rather than during,the cytokine treatment and islets are incubated for 4 h, further nitric oxide synthesis is prevented and most cytokine-induced strand breaks are no longer seen. To investigate DNA repair following cytokine treatment, cells were transferred to fresh medium and incubated for 4 h in the presence of hydroxyurea (HU) and 1-beta-D-arabinosyl cytosine (AraC), as inhibitors of strand rejoining. In the presence of these inhibitors there was an accumulation of strand breaks that would otherwise have been repaired. However, when further nitric oxide synthesis was inhibited by NMMA, significantly less additional strand breakage was seen in the presence of HU and AraC. We interpret this, as indicating that excision repair of previously induced base damage did not contribute significantly to strand breakage. Levels of oxidised purines, as indicated by formamidopyrimidine glycosylase (Fpg) sensitive sites, were not increased in cytokine-treated islets. We conclude that in these primary insulin-secreting cells: (a) the DNA damage induced by an 18h cytokine treatment is prevented by an inhibitor of nitric oxide synthase, (b) much of the damage is in the form of apparent strand breaks rather than altered bases such as oxidised purines, (c) substantial repair is ongoing during the cytokine treatment and this repair is not inhibited in the presence of nitric oxide.     

Hyperthermia inhibits homologous recombination repair and sensitizes cells to ionizing radiation in a time‐ and temperature‐dependent manner

Hyperthermia has long been known as a radio‐sensitizing agent that displays anti‐tumor effects, and has been developed as a therapeutic application. The mechanisms of hyperthermia‐induced radio‐sensitization are highly associated with inhibition of DNA repair. Our investigations aimed to show how hyperthermia inactivate homologous recombination repair in the process of sensitizing cells to ionizing radiation by using a series of DNA repair deficient Chinese Hamster cells. Significant differences in cellular toxicity attributable to hyperthermia at and above 42.5°C were observed. In wild‐type and non‐homologous end joining repair mutants, cells in late S phase showed double the amount heat‐induced radio‐sensitization effects of G1‐phase cells. Both radiation‐induced DNA double strand breaks and chromatin damage resulting from hyperthermia exposure was measured to be approximately two times higher in G2‐phase cells than G0/G1 cells. Additionally, G2‐phase cells took approximately two times as long to repair DNA damage over time than G0/G1‐phase cells. To supplement these findings, radiation‐induced Rad51 foci formations at DNA double strand break sites were observed to gradually dissociate in response to the temperature and time of hyperthermia exposure. Dissociated Rad51 proteins subsequently re‐formed foci at damage sites with time, and occurred in a trend also related to temperature and time of hyperthermia exposure. These findings suggest Rad51's dissociation and subsequent reformation at DNA double strand break sites in response to varying hyperthermia conditions plays an important role in hyperthermia‐induced radio‐sensitization. J. Cell. Physiol. 228: 1473–1481, 2013. © 2012 Wiley Periodicals, Inc.     

DNA damage in HeLa S3 cells by an antitumor drug ledakrin and other antitumor 1-nitro-9-aminoacridines

Ledakrin and seven other antitumor and cytotoxic derivatives of 1-nitro-9-aminoacridine were shown to induce DNA-single strand breaks in HeLa S3 cells as found by alkaline sucrose gradient centrifugation. The induced DNA damage is of non-random character. Some of Ledakrin-induced DNA breaks are probably generated by endonucleolytic cleavage in the course of repair processes as indicated by experiments with Novobiocin, an antibiotic preventing the incision step of DNA repair. Other Ledakrin-induced DNA breaks observed on alkaline sucrose gradients may arise from alkali-labile sites in DNA. Most of such sites seem to be converted to breaks after brief exposure to alkali. The extent of DNA damage by 1-nitro-9-aminoacridines was found to be correlated with cytotoxic activities of these compounds against HeLa S3 cells. Furthermore, Ledakrin and other derivatives seem to induce DNA-repair synthesis in HeLa S3 cells as judged by the stimulation of hydroxyurea (HU)-resistant incorporation of [³H] thymidine into DNA. The agents studied differ in their concentrations required to produce a considerable stimulation of DNA repair, whereas the maximal level of this effect is similar for all the derivatives assayed. The former values are correlated with cytotoxic activites of these compounds and seem to reflect the overall extent of DNA damage by 1-nitro-9-aminoacridines. Stimulation of DNA-repair synthesis is gradually shut off during prolonged incubation of the cells with Ledakrin or during postincubation of the cells in a drug-free medium. Such postincubation results also in the gradual accumulation of DNA-single strand breaks as observed by alkaline sucrose centrifugation. Hence, HeLa S3 cells are incapable of efficiently removing DNA damage by 1-nitro-9-aminoacridines, though the drug's action activates temporarily some repair mechanisms.The reported results suggest that overall DNA damage may contribute to the cytotoxic effects of 1-nitro-9-aminoacridines besides previously found ability of these agents to form interstrand DNA cross-links.     

Early nuclear events in lymphocyte proliferation : The role of DNA strand break repair and ADP ribosylation

The previously reported extensive DNA strand breakage in resting murine splenic lymphocytes is not an artifact of the extraction or assay procedure. The benzamide inhibitors of poly(ADP ribose) synthetase (pADPRS), such as 5-methoxybenzamide (MBA), had been shown to block the strand break repair occurring within 2 h of activation of splenic lymphocytes by the mitogen concanavalin A (conA); the inhibitors also blocked early events in proliferation, such as blast formation, as well as entry into S phase. Inhibitors of pADPRS blocked lymphocyte proliferation by inhibiting the activity of this enzyme, rather than by non-specific effects. Aphidicolin, an inhibitor of alpha-polymerase, also prevented DNA strand break repair in conA-stimulated cells but, unlike MBA, did not prevent blast formation. DNA strand breaks accumulated in the presence of MBA at the same linear rate (300-400/h) in both resting and conA-treated cells. We and others had hypothesized that this accumulation was due to a continuous production of strand breaks in lymphocytes, leading to their accumulation in presence of repair inhibitors. However, incubation of the cells with aphidicolin at concentrations that inhibited repair did not result in any increase in strand breaks. The hypothesis of continuous cycling of breaks is incorrect; accumulation of breaks was due to some indirect effect of MBA, such as a possible disinhibition of an ADP-ribosylation-sensitive endonuclease described in other cell types. All of the early stages of lymphocyte proliferation, including blast transformation (but not DNA synthesis) require ADP ribosylation. Repair of DNA strand breaks is not a precondition for blast formation, though experiments involving the combined effects of MBA and aphidicolin showed that repair of the breaks is essential in order for the cells to replicate their DNA. Our data are consistent with a model suggesting that DNA strand breaks introduced into differentiated cells act as an additional safety-catch mechanism that restrains them from replicating their genetic material but not from undergoing the early stages of proliferation.     

Association of poly(ADP-rib) synthesis with cessation of DNA synthesis and DNA fragmentation

CHO cells and cs-4-D3 cells were used to investigate the association between poly(ADP-rib) synthesis and the cessation of DNA synthesis and DNA fragmentation. The cs4-D3 cells are cold-sensitive DNA synthesis arrest mutants of CHO cells. Upon incubation at 33 degrees C, DNA synthesis in the cs4-D3 cells stops and the cells enter a prolonged G1 or G0 phase. The events that occurred when cs4 cells were incubated at 33 degrees C were similar to those that occurred when wild-type CHO cells grew to high density. (1) In both cases, DNA synthesis and cell growth stopped. (2) The NAD+ concentration/cell was 20-25% lower in growth-arrested cells than in logarithmically growing cells. (3) Poly(ADP-rib) synthesis was 3-4 fold higher in growth-arrested cells than in logarithmically growing cells. (4) The growth-inhibited cells developed DNA strand breaks which resulted in large percentages of their DNA appearing in the low molecular weight range of alkaline sucrose gradients. (5) Both the increased rate of poly(ADP-rib) synthesis and the development of DNA strand breaks appears to be characteristic of the G1 phase of the cell cycle. (6) When growth-inhibited cells were restored to conditions favorable for DNA synthesis and cell growth, the DNA strand breaks were repaired. (7) Prolonged incubation under growth-restrictive conditions resulted in the accumulation of more DNA strand breaks than the cells could repair. This was followed by cell death when the cells were restored to conditions favorable for cell growth.     

Suppressive effect of novobiocin on the frequency of chromosome-type aberrations induced by ara C in the G1 phase of human lymphocytes

1-beta-D-Arabinofuranosylcytosine (ara C) induces chromosome-type aberrations in mammalian cells by inhibiting repair replication in the G1 phase. The effect of novobiocin, an inhibitor of prokaryotic gyrases, on G1 repair in human cells was studied cytogenetically using this characteristic of ara C. The experiment was based on the assumption that if novobiocin inhibits the relaxation of chromatin required prior to repair replication, it would reduce the frequency of chromosome-type aberrations in cells treated with a mutagen followed by posttreatment with ara C. It has also been shown that in lymphocytes ara C induces chromosome-type aberrations which were not caused by any induced DNA lesion, and that the frequency of these aberrations changes with the age of the blood donor. The effect of novobiocin on the frequency of chromosome-type aberrations induced by ara C in lymphocytes without mutagen pretreatment was also investigated for blood samples from donors of different ages. Human peripheral blood lymphocytes, which were either untreated of treated with 4-nitroquinoline-N-oxide (4NQO) or methyl methanesulfonate (MMS), were posttreated in their early G1 phase with ara C only or ara C and novobiocin. The resulting chromosome-type aberrations were observed in cells in their first mitoses, and a comparison was made between the frequency of aberrations occurring in the presence of novobiocin and in its absence. The results showed that novobiocin reduced the frequency of chromosome-type aberrations induced by ara C in both mutagen-pretreated and -non-pretreated cells, and that lymphocytes from younger donors were less sensitive to novobiocin. The present study demonstrated cytogenetically the existence of a novobiocin-sensitive process to induce chromosome recombination in G1 lymphocytes.     

Cohesin promotes the repair of ionizing radiation-induced DNA double-strand breaks in replicated chromatin

The cohesin protein complex holds sister chromatids together after synthesis until mitosis. It also contributes to post-replicative DNA repair in yeast and higher eukaryotes and accumulates at sites of laser-induced damage in human cells. Our goal was to determine whether the cohesin subunits SMC1 and Rad21 contribute to DNA double-strand break repair in X-irradiated human cells in the G2 phase of the cell cycle. RNA interference-mediated depletion of SMC1 sensitized HeLa cells to X-rays. Repair of radiation-induced DNA double-strand breaks, measured by γH2AX/53BP1 foci analysis, was slower in SMC1- or Rad21-depleted cells than in controls in G2 but not in G1. Inhibition of the DNA damage kinase DNA-PK, but not ATM, further inhibited foci loss in cohesin-depleted cells in G2. SMC1 depletion had no effect on DNA single-strand break repair in either G1 or late S/G2. Rad21 and SMC1 were recruited to sites of X-ray-induced DNA damage in G2-phase cells, but not in G1, and only when DNA damage was concentrated in subnuclear stripes, generated by partially shielded ultrasoft X-rays. Our results suggest that the cohesin complex contributes to cell survival by promoting the repair of radiation-induced DNA double-strand breaks in G2-phase cells in an ATM-dependent pathway.     

Repair of Cytokine-induced DNA Damage in Cultured Rat Islets of Langerhans

Treatment of cultured rat pancreatic islets of Langerhans with the combined cytokines interleukin-1β (IL-1β), interferon γ (IFN γ) and tumour necrosis factor α (TNF α) leads to DNA damage including strand breakage. We have investigated the nature of this damage and its repairability. When islets are further incubated for 4?h in fresh medium, the level of cytokine-induced strand breakage remains constant. If the nitric oxide synthase inhibitor N^G-monomethyl-l-arginine (NMMA) is present during cytokine treatment, then strand breakage is prevented. If NMMA is added following, rather than during, the cytokine treatment and islets are incubated for 4?h, further nitric oxide synthesis is prevented and most cytokine-induced strand breaks are no longer seen. To investigate DNA repair following cytokine treatment, cells were transferred to fresh medium and incubated for 4?h in the presence of hydroxyurea (HU) and 1-β-d-arabinosyl cytosine (AraC), as inhibitors of strand rejoining. In the presence of these inhibitors there was an accumulation of strand breaks that would otherwise have been repaired. However, when further nitric oxide synthesis was inhibited by NMMA, significantly less additional strand breakage was seen in the presence of HU and AraC. We interpret this, as indicating that excision repair of previously induced base damage did not contribute significantly to strand breakage. Levels of oxidised purines, as indicated by formamidopyrimidine glycosylase (Fpg) sensitive sites, were not increased in cytokine-treated islets. We conclude that in these primary insulin-secreting cells: (a) the DNA damage induced by an 18?h cytokine treatment is prevented by an inhibitor of nitric oxide synthase, (b) much of the damage is in the form of apparent strand breaks rather than altered bases such as oxidised purines, (c) substantial repair is ongoing during the cytokine treatment and this repair is not inhibited in the presence of nitric oxide.     

P element excision and repair by non-homologous end joining occurs in both G1 and G2 of the cell cycle

P element excision generates a DNA double-strand break at the transposon donor site. Genetic studies have demonstrated a strong bias toward repair of P element-induced DNA breaks by homologous recombination with the sister chromatid, suggesting that P element excision occurs after DNA replication, in G2 of the cell cycle. We developed methods to arrest Drosophila tissue culture cells and assay P element excision in either G1- or G2-arrested cells. Dacapo or tribbles transgene expression arrests cells in either G2 or G2, respectively. RNA-mediated gene interference (RNAi) directed against cyclin E or cyclin A arrests cells in G1 or G2, respectively. P element excision occurs efficiently in both G1- and G2-arrested cells, suggesting that cell cycle regulation of P element transposase does not occur in our somatic cell system. DNA double-strand break repair occurs by two predominant mechanisms: homologous recombination (HR) and non-homologous end joining (NHEJ). HR is thought to be restricted to the post-replicative, G2, phase of the cell cycle, while NHEJ may occur throughout the cell cycle. Our results indicate that NHEJ repair of an extrachromasomal plasmid substrate occurs at least as efficiently in G2-arrested cells as in asynchronous cells or in G1-arrested cells.     

DNA repair and chromosomal alterations

All mutagenic agents induce lesions in the cellular DNA and they are repaired efficiently by different repair mechanisms. Un-repaired and mis-repaired lesions lead to chromosomal aberrations (CAs). Depending upon the mutagenic agents involved, different DNA repair pathways, such as nucleotide excision repair (NER), base excision repair (BER), non-homologous end joining (NHEJ), homologous recombination repair (HRR), cross-link repair (FANC), single strand annealing (SSA) etc., are operative. Following ionising radiation, DNA double strand breaks (DSBs, which are considered to be the most important leasion leading to observed biological effects) are repaired either by NHEJ and/or HRR. We have investigated the relative role of these two repair pathways leading to chromosomal aberrations using Chinese hamster ovary (CHO) mutant cells deficient in one of these two repair pathwatys. NHEJ operates both in G1 and G2 phases of the cell cycle, wheras HHR operates mainly in S and G2 phases of the cell cycle. In NHEJ-deficient mutant cells irradiated in G1, un-repaired double strand breaks reaching S phase are repaired (unexpectedly with a large mis-repair component) by HRR. In HRR-deficient mutant cells, un-repaired DSBs reaching S phase are repaired by NHEJ (unexpectedly with a low mis-repair component) as evidenced by the frequencies of chromatid type aberrations. Employing a similar approach, following treatment with benzo(alpha)pyrene-7,8diol-9,10epoxide (BPDE), the active metabolite of benzo(alpha)pyrene, NER and HRR seem to be the most important repair pathways protecting against chromosomal damage induced by this agent. In the case of acetaldehyde, (primary metabolite of alcohol in vivo) a DNA cross-linking agent, HRR and FANC pathways are important for protection against damage induced by this agent. Irrespective of the type of DNA lesions induced, ultimately they have to be converted to DSBs in order to give rise to CA. Therefore, both NHEJ and HRR are also involved to some extent in the origin of CA following treatment with S-dependent agents.The relative importance of different repair pathways in bestowing protection against DNA damage leading to chromosomal alterations is discussed.     

Macrophage-mediated cytostatic activity blocks lymphoblast cell cycle progression independently in both G1 phase and S phase

Recent work has shown that macrophage-mediated cytostatic activity inhibits cell cycle traverse in G1 and/or S phase of the cell cycle without affecting late S, G2, or M phases. The present report is directed at distinguishing between such cytostatic effects on G1 phase or S phase using the accumulation of DNA polymerase alpha as a marker of G1 to S phase transition. Quiescent lymphocytes stimulated with concanavalin A undergo a semisynchronous progression from G0 to G1 to S phase with a dramatic increase in DNA polymerase alpha activity between 20 and 30 hr after stimulation. This increase in enzyme activity was inhibited, as was the accumulation of DNA, when such cells were cocultured with activated murine peritoneal macrophages during this time interval. However, if mitogen-stimulated lymphocytes were enriched for S-phase cells by centrifugal elutriation and cocultured with activated macrophages for 4-6 hr, DNA synthesis was inhibited but the already elevated DNA-polymerase activity was unaffected. Similar results were obtained when a virally transformed lymphoma cell line was substituted as the target cell in this assay. These results show that both G1 and S phase of the cycle are inhibited and suggest that inhibition of progression through the different phases may be accomplished by at least two distinct mechanisms.     

Cell cycle-dependent strand bias for UV-induced mutations in the transcribed strand of excision repair-proficient human fibroblasts but not in repair-deficient cells.

To study the effect of nucleotide excision repair on the spectrum of mutations induced in diploid human fibroblasts by UV light (wavelength, 254 nm), we synchronized repair-proficient cells and irradiated them when the HPRT gene was about to be replicated (early S phase) so that there would be no time for repair in that gene before replication, or in G1 phase 6 h prior to S, and determined the kinds and location of mutations in that gene. As a control, we also compared the spectra of mutations induced in synchronized populations of xeroderma pigmentosum cells (XP12BE cells, which are unable to excise UV-induced DNA damage). Among the 84 mutants sequenced, base substitutions predominated. Of the XP mutants from S or G1 and the repair-proficient mutants from S, approximately 62% were G.C----A.T. In the repair-proficient mutants from G1, 47% were. In mutants from the repair-proficient cells irradiated in S, 71% (10 of 14) of the premutagenic lesions were located in the transcribed strand; with mutants from such cells irradiated in G1, only 20% (3 of 15) were. In contrast, there was no statistically significant difference in the fraction of premutagenic lesions located in the transcribed strand of the XP12BE cells; approximately 75% (24 of 32) of the premutagenic lesions were located in that strand, i.e., 15 of 19 (79%) in the S-phase cells and 9 of 13 (69%) in the G1-phase cells. The switch in strand bias supports preferential nucleotide excision repair of UV-induced damage in the transcribed strand of the HPRT gene.     

Sensitivity of excision repair in normal human,xeroderma pigmentosum variant and Cockayne's syndrome fibroblasts to inhibition by cytosine arabinoside

Inhibition of the gap-filling, polymerizing step of excision repair by 1-β-D-arabinofuranosylcytosine (ara-C) after irradiation with ultraviolet light in human diploid fibroblasts resulted in the formation of persistent DNA strand breaks in G₁, G₂, and plateau phase cells, but not in S phase cells. Addition of hydroxyurea to ara-C resulted in partial inhibition of repair in S phase cells. These observations can be explained either in terms of changing roles in repair for different DNA polymerases throughout the cell cycle or by the presence of a pool of deoxycytidine nucleotides during S phase equivalent to an external source of deoxycytidine at 50 μM concentration. A similar concentration dependence on ara-C was observed for inhibition of repair in normal human, xeroderma pigmentosum (XP) variant, and Cockayne's syndrome cells. Ara-C produced a similar number of breaks in normal and Cockayne's syndrome cells but slightly more in XP variant cells. Exonuclease III and S1 nuclease independently both degraded about 50% of the ₃H-thymidine incorporated into repaired regions in the presence of ara-C. Sequential digestion with both enzymes degraded nearly 90% of the repaired regions. These observations can be explained if excision repair proceeds by displacing the damaged strand so that both the ₃H-labeled patch and the damaged region are still ligated to high molecular weight DNA and compete for the same complementary strand during in vitro incubation with the nucleases. The amount of ₃H-thymidine incorporated in DNA by repair decreased with increasing concentrations of ara-C and hydroxyurea, suggesting that the incomplete patches became shorter under these conditions. Extrapolation of the digestion kinetics with exonuclease III permits an estimate of the normal patch size of about 100 nucleotides, consistent with previous estimates.     

E2F1 is involved in DNA single-strand break repair through cell-cycle-dependent upregulation of XRCC1 expression

The X-ray repair cross complementing group 1 (XRCC1) protein is involved in DNA base excision repair and its expression varies during the cell cycle. Although studies have demonstrated that rapid XRCC1-dependent single-strand break repair (SSBR) takes place specifically during S/G(2) phases, it remains unclear how it is regulated during the cell cycle. We found that XRCC1 is a direct regulatory target of E2F1 and further investigated the role of XRCC1 in DNA repair during the cell cycle. Saos2 primary osteosarcoma cells stably transfected with inducible E2F1-wt or mutant E2F1-132E were treated with hydroxurea (HU) for 36h and were subsequently withdrawn HU for 2-24h to test whether cell-cycle-dependent DNA SSBR requires E2F1-mediated upregulation of XRCC1. We found that SSBR activity, as determined using a qPCR-base method, was correlated with E2F1 levels at different phases of the cell cycle. XRCC1-positive (AA8) and negative (EM9) CHO cells were used to demonstrate that the alterations in SSBR were mediated by XRCC1. The results indicate that E2F1-mediated regulation of XRCC1 is required for cell-cycle-dependent SSBR predominantly in G(1)/S phases. Our observations have provided new mechanistic insight for understanding the role of E2F1 in the maintenance of genomic stability and cell survival during the cell cycle. The regulation of XRCC1 by E2F1 during cell-cycle-dependent SSBR might be an important aspect for practical consideration for resolving the problem of drug resistance in tumor chemotherapies.