Mechanism of radiosensitization by halogenated pyrimidines: effect of BrdU on repair of DNA breaks, interphase chromatin breaks, and potentially lethal damage in plateau-phase CHO cells.

There is evidence suggesting that radiosensitization induced in mammalian cells by substitution in the DNA of thymidine with BrdU has a component that relies on inhibition of repair and/or fixation of radiation damage. Here, experiments designed to study the mechanism of this phenomenon are described. The effect of BrdU incorporation into DNA was studied on cellular repair capability, rejoining of interphase chromosome breaks, as well as induction and rejoining of DNA double- and single-stranded breaks (DSBs and SSBs) in plateau-phase CHO cells exposed to X rays. Repair of potentially lethal damage (PLD), as measured by delayed plating of plateau-phase cells, was used to assay cellular repair capacity. Rejoining of interphase chromosome breaks was assayed by means of premature chromosome condensation (PCC); induction and rejoining of DNA DSBs were assayed by pulsed-field gel electrophoresis and induction and rejoining of DNA SSBs by DNA unwinding. A decrease was observed in the rate of repair of PLD in cells grown in the presence of BrdU, the magnitude of which depended upon the degree of thymidine replacement. The relative increase in survival caused by PLD repair was larger in cells substituted with BrdU and led to a partial loss of the radiosensitizing effect compared to cells tested immediately after irradiation. A decrease was also observed in the rate of rejoining of interphase chromosome breaks as well as in the rate of rejoining of the slow component of DNA DSBs in cells substituted with BrdU. The time constants measured for the rejoining of the slow component of DNA DSBs and of interphase chromosome breaks were similar both in the presence and in the absence of BrdU, suggesting a correlation between this subset of DNA lesions and interphase chromosome breaks. It is proposed that a larger proportion of radiation-induced potentially lethal lesions becomes lethal in cells grown in the presence of BrdU. Potentially lethal lesions are fixed via interaction with processes associated with cell cycle progression in cells plated immediately after irradiation, but can be partly repaired in cells kept in the plateau-phase. It is hypothesized that fixation of PLD is caused by alterations in chromatin conformation that occur during normal progression of cells throughout the cell cycle.(ABSTRACT TRUNCATED AT 400 WORDS)     

A Functional Link Between SIRT1 Deacetylase and NBS1 in DNA Damage Response

In mammalian cells, DNA is often subjected to stresses such as ionizing radiation (IR) and ultraviolet light that can induce DNA double strand breaks (DSBs). In response to DNA DSBs, mammalian cells activate a rapid phosphorylation signaling cascade through the protein kinases, Ataxia-Telangiectasia Mutated (ATM) and ATM- and Rad3-Related (ATR).1 Many well-characterized DNA repair factors are phosphorylated by ATM in response to DSBs, and the sequential phosphorylation of some of these factors, including NBS1, delay cell cycle progression (checkpoint arrest) to allow time for DNA damage repair.2 Results from a new study suggest that phosphorylation of NBS1 is regulated by the acetylation status of the protein, which is modulated by SIRT1 deacetylase.     

Cell division transforms mutagenic lesions into deletion-recombinagenic lesions in yeast cells.

Cell proliferation has been recognized as an important factor in human and experimental carcinogenesis. Point mutations as well as larger chromosomal rearrangements are involved in the initiation of cancer. In this paper we compared the relative potencies of radiation and chemical carcinogens for inducing point mutations vs. deletions in cell cycle arrested with dividing cells of Saccharomyces cerevisiae. Point mutation substrates and deletion (DEL) recombination substrates were constructed with the genes CDC28 and TUB2 that are required for cell cycle progression through G1 and G2, respectively. The carcinogens ionizing radiation, UV, MMS, EMS and 4-NQO induced point mutations in G1 and in G2 arrested as well as in dividing cells. UV, MMS, EMS and 4-NQO caused very weak if any increases in DEL recombination in G1 or G2 arrested cells, but large increases in dividing cells. When cells treated with carcinogen either in G1 or G2 were allowed to progress through the cell cycle, a time-dependent increase in DEL recombination was seen. Ionizing radiation and the site-specific endonuclease I-SceI, which both directly create double-strand breaks, induced DEL recombination in G1 as well as in G2 arrested cells. In conclusion, UV-, MMS-, EMS- and 4-NQO-induced DNA damage was converted during DNA replication to a lesion capable of inducing DEL recombination which is probably a DNA strand break. Thus, cell proliferation is not necessary to turn DNA alkylation or UV damage into a mutagenic lesion but to convert the damage into a lesion that induces DNA deletions. These results are discussed with respect to mechanisms of carcinogenesis.     

Localization of checkpoint and repair proteins in eukaryotes

In eukaryotes, the cellular response to DNA damage depends on the type of DNA structure being recognized by the checkpoint and repair machinery. DNA ends and single-stranded DNA are hallmarks of double-strand breaks and replication stress. These two structures are recognized by distinct sets of proteins, which are reorganized into a focal assembly at the lesion. Moreover, the composition of these foci is coordinated with cell cycle progression, reflecting the favoring of end-joining in the G1 phase and homologous recombination in S and G2. The assembly of proteins at sites of DNA damage is largely controlled by a network of protein-protein interactions, with the Mre11 complex initiating assembly at DNA ends and replication protein A directing recruitment to single-stranded DNA. This review summarizes current knowledge on the cellular organization of DSB repair and checkpoint proteins focusing on budding yeast and mammalian cells.     

Replication fork integrity and intra-S phase checkpoint suppress gene amplification

Gene amplification is a phenotype-causing form of chromosome instability and is initiated by DNA double-strand breaks (DSBs). Cells with mutant p53 lose G1/S checkpoint and are permissive to gene amplification. In this study we show that mammalian cells become proficient for spontaneous gene amplification when the function of the DSB repair protein complex MRN (Mre11/Rad50/Nbs1) is impaired. Cells with impaired MRN complex experienced severe replication stress and gained substrates for gene amplification during replication, as evidenced by the increase of replication-associated single-stranded breaks that were converted to DSBs most likely through replication fork reversal. Impaired MRN complex directly compromised ATM/ATR-mediated checkpoints and allowed cells to progress through cell cycle in the presence of DSBs. Such compromised intra-S phase checkpoints promoted gene amplification independently from mutant p53. Finally, cells adapted to endogenous replication stress by globally suppressing genes for DNA replication and cell cycle progression. Our results indicate that the MRN complex suppresses gene amplification by stabilizing replication forks and by securing DNA damage response to replication-associated DSBs.     

Initiating the Uninitiated: Replication of damaged DNA and Carcinogenesis

Cancer is a genetic disease and carcinogenesis is the process whereby the relevant genetic alterations are acquired. Environmental carcinogens may damage DNA to induce mutations and chromosomal aberrations as permanent heritable changes in the genome that initiate carcinogenesis. For many carcinogens initiation of carcinogenesis requires the initiation of DNA replication suggesting that genetic alterations are fixed in the genome during replication of damaged DNA. It is of great interest to understand the mechanisms whereby carcinogen-induced damage to DNA causes mutations and chromosomal aberrations, and how cells may resist such events. It is clear now that cells express a complex repertoire of responses to DNA damage including several pathways of DNA repair and cell cycle checkpoints that protect against carcinogenesis. This commentary is concerned with the protective influence of DNA damage checkpoints that delay or arrest progression through the cell division cycle and especially with the responses of S phase cells to the environmental carcinogens UV and benzo[a]pyrene diolepoxide I (BPDE). Recent studies indicate that checkpoint responses may act at the very point of replication of damaged DNA to slow DNA chain elongation, inhibit replicon initiation, and suppress initiation of carcinogenesis.     

DNA damage during mitosis in human cells delays the metaphase/anaphase transition via the spindle-assembly checkpoint

BACKGROUND: DNA damage during mitosis triggers an ATM kinase-mediated cell cycle checkpoint pathway in yeast and fly embryos that delays progression through division. Recent data suggest that this is also true for mammals. Here we used laser microsurgery and inhibitors of topoisomerase IIalpha to break DNA in various mammalian cells after they became committed to mitosis. We then followed the fate of these cells and emphasized the timing of mitotic progression, spindle structure, and chromosome behavior. RESULTS: We find that DNA breaks generated during late prophase do not impede entry into prometaphase. If the damage is minor, cells complete mitosis on time. However, more significant damage substantially delays exit from mitosis in many cell types. In human (HeLa, CFPAC-1, and hTERT-RPE) cells, this delay occurs during metaphase, after the formation of a bipolar spindle and the destruction of cyclin A, and it is not dependent on a functional p53 pathway. Pretreating cells with ATM kinase inhibitors does not abrogate the metaphase delay due to chromosome damage. Immunofluorescence studies reveal that cells blocked in metaphase by chromosome damage contain one or more Mad2-positive kinetochores, and the block is rapidly overridden when the cells are microinjected with a dominant-negative construct of Mad2 (Mad2deltaC). CONCLUSIONS: We conclude that the delay in mitosis induced by DNA damage is not due to an ATM-mediated DNA damage checkpoint pathway. Rather, the damage leads to defects in kinetochore attachment and function that, in turn, maintain the intrinsic Mad-2-based spindle assembly checkpoint.     

Listeria monocytogenes induces host DNA damage and delays the host cell cycle to promote infection

Listeria monocytogenes (Lm) is a human intracellular pathogen widely used to uncover the mechanisms evolved by pathogens to establish infection. However, its capacity to perturb the host cell cycle was never reported. We show that Lm infection affects the host cell cycle progression, increasing its overall duration but allowing consecutive rounds of division. A complete Lm infectious cycle induces a S-phase delay accompanied by a slower rate of DNA synthesis and increased levels of host DNA strand breaks. Additionally, DNA damage/replication checkpoint responses are triggered in an Lm dose-dependent manner through the phosphorylation of DNA-PK, H2A.X, and CDC25A and independently from ATM/ATR. While host DNA damage induced exogenously favors Lm dissemination, the override of checkpoint pathways limits infection. We propose that host DNA replication disturbed by Lm infection culminates in DNA strand breaks, triggering DNA damage/replication responses, and ensuring a cell cycle delay that favors Lm propagation.     

Hypersensitivity to radiation-induced non-apoptotic and apoptotic death in cell lines from patients with the ICF chromosome instability syndrome

Immunodeficiency, centromeric region instability, and facial anomalies (ICF), a rare recessive chromosome instability syndrome, involves the loss of DNA methyltransferase 3B activity and the consequent hypomethylation of a small portion of the genome. We demonstrate for the first time that ICF cells are strongly hypersensitive to a genotoxic agent, namely, ionizing radiation. However, unlike cell lines from patients with ataxia telangiectasia or Nijmegen breakage syndrome, chromosome instability syndromes also associated with unusual sensitivity to ionizing radiation, ICF cells did not show any deficiencies in their cell cycle checkpoints. ICF lymphoblastoid cell lines demonstrated increased apoptosis, long-term cell cycle arrest, and loss of viability in clonogenicity assays after irradiation compared to analogous normal cell lines. Also, the ICF cell lines were subject to high frequencies of rapid non-apoptotic cell death upon irradiation but not to abnormally high levels of radiation-induced, cytogenetically detectable chromosome abnormalities. ICF-associated undermethylation of some regulatory gene(s) might lead to an exaggerated response to radiation-induced breaks in DNA yielding increased rates of cell death and irreversible cell cycle arrest. As a defense against their frequent spontaneous breaks in chromosomes 1 and 16, ICF patients may be abnormally prone to chromosome break-induced apoptosis, non-apoptotic cell death, and permanent cell cycle arrest so as to minimize the number of cycling cells with spontaneous rearrangements. A similarly increased cell death and cycle-arrest response to chromosome breaks due to cancer-linked DNA hypomethylation might occur during carcinogenesis.     

RAD51 paralogs: roles in DNA damage signalling, recombinational repair and tumorigenesis

Chromosomal double-strand breaks (DSBs) have the potential to permanently arrest cell cycle progression and endanger cell survival. They must therefore be efficiently repaired to preserve genome integrity and functionality. Homologous recombination (HR) provides an important error-free mechanism for DSB repair in mammalian cells. In addition to RAD51, the central recombinase activity in mammalian cells, a family of proteins known as the RAD51 paralogs and consisting of five proteins (RAD51B, RAD51C, RAD51D, XRCC2 and XRCC3), play an essential role in the DNA repair reactions through HR. The RAD51 paralogs act to transduce the DNA damage signal to effector kinases and to promote break repair. However, their precise cellular functions are not fully elucidated. Here we discuss recent advances in our understanding of how these factors mediate checkpoint responses and act in the HR repair process. In addition, we highlight potential functional similarities with the BRCA2 tumour suppressor, through the recently reported links between RAD51 paralog deficiencies and tumorigenesis triggered by genome instability.     

Activation of the G2 cell cycle checkpoint enhances survival of epithelial cells exposed to hyperoxia

Reactive oxygen species produced during hyperoxia damage DNA, inhibit proliferation in G1- through p53-dependent activation of p21(Cip1/WAF1/Sdi1), and kill cells. Because checkpoint activation protects cells from genotoxic stress, we investigated cell proliferation and survival of the murine type II epithelial cell line MLE15 during hyperoxia. These cells were chosen for study because they express Simian large and small-T antigens, which transform cells in part by disrupting the p53-dependent G1 checkpoint. Cell counts, 5-bromo-2'-deoxyuridine labeling, and flow cytometry revealed that hyperoxia slowed cell cycle progression after one replication, resulting in a pronounced G2 arrest by 72 h. Addition of caffeine, which inactivates the G2 checkpoint, diminished the percentage of hyperoxic cells in G2 and increased the percentage in sub-G1 and G1. Abrogation of the G2 checkpoint was associated with enhanced oxygen-induced DNA strand breaks and cell death. Caffeine did not affect DNA integrity or viability of cells exposed to room air. Similarly, caffeine abrogated the G2 checkpoint in hyperoxic A549 epithelial cells and enhanced oxygen-induced toxicity. These data indicate that hyperoxia rapidly inhibits proliferation after one cell cycle and that the G2 checkpoint is critical for limiting DNA damage and cell death.     

Chronic Exposure to Combined Carcinogens Enhances Breast Cell Carcinogenesis with Mesenchymal and Stem-Like Cell Properties

Breast cancer is the most common type of cancer affecting women in North America and Europe. More than 85% of breast cancers are sporadic and attributable to long-term exposure to small quantities of multiple carcinogens. To understand how multiple carcinogens act together to induce cellular carcinogenesis, we studied the activity of environmental carcinogens 4-(methylnitrosamino)-1-(3-pyridyl)-1-butanone (NNK) and benzo[a]pyrene (B[a]P), and dietary carcinogen 2-amino-1-methyl-6-phenylimidazo[4,5-b]pyridine (PhIP) using our breast cell carcinogenesis model. Our study revealed, for the first time, that combined NNK and B[a]P enhanced breast cell carcinogenesis chronically induced by PhIP in both non-cancerous and cancerous breast cells. Co-exposure was more potent than sequential exposure to combined NNK and B[a]P followed by PhIP in inducing carcinogenesis. Initiation of carcinogenesis was measured by transient endpoints induced in a single exposure, while progression of carcinogenesis was measured by acquisition of constitutive endpoints in cumulative exposures. Transient endpoints included DNA damage, Ras-Erk-Nox pathway activation, reactive oxygen species elevation, and increased cellular proliferation. Constitutive endpoints included various cancer-associated properties and signaling modulators, as well as enrichment of cancer stem-like cell population and activation of the epithelial-to-mesenchymal transition program. Using transient and constitutive endpoints as targets, we detected that a combination of the green tea catechins ECG and EGCG, at non-cytotoxic levels, was more effective than individual agents in intervention of cellular carcinogenesis induced by combined NNK, B[a]P, and PhIP. Thus, use of combined ECG and EGCG should be seriously considered for early intervention of breast cell carcinogenesis associated with long-term exposure to environmental and dietary carcinogens.     

Retinol supplementation induces DNA damage and modulates iron turnover in rat Sertoli cells

Recent intervention studies revealed that supplementation with retinoids resulted in a higher incidence of lung cancer. Recently the causal mechanism has begun to be clarified. We report here that retinol caused cellular DNA damage probably involving cellular iron accumulation. Retinol (7μM) significantly induced DNA single strands breaks, DNA fragmentation and production of 8-oxo-7, 8-dihydro-2′-deoxyguanosine in cultured Sertoli cells. In contrast, lower doses seemed not to induce single-strands break in this experimental model. The breaks in DNA were inhibited by an iron scavenger; and 7μM retinol treatment modulated iron turnover leading to iron accumulation, suggesting that iron ions were required for the retinol cellular effects. These findings suggest that retinol-induced DNA damage was associated with the modulation of iron turnover, and these characteristics could be responsible for the increased incidence of lung cancer associated with retinoids supplementation.     

Retinol supplementation induces DNA damage and modulates iron turnover in rat Sertoli cells

Recent intervention studies revealed that supplementation with retinoids resulted in a higher incidence of lung cancer. Recently the causal mechanism has begun to be clarified. We report here that retinol caused cellular DNA damage probably involving cellular iron accumulation. Retinol (7μM) significantly induced DNA single strands breaks, DNA fragmentation and production of 8-oxo-7, 8-dihydro-2'-deoxyguanosine in cultured Sertoli cells. In contrast, lower doses seemed not to induce single-strands break in this experimental model. The breaks in DNA were inhibited by an iron scavenger; and 7μM retinol treatment modulated iron turnover leading to iron accumulation, suggesting that iron ions were required for the retinol cellular effects. These findings suggest that retinol-induced DNA damage was associated with the modulation of iron turnover, and these characteristics could be responsible for the increased incidence of lung cancer associated with retinoids supplementation.     

The consequences of Rad51 overexpression for normal and tumor cells

The Rad51 recombinase is an essential factor for homologous recombination and the repair of DNA double strand breaks, binding transiently to both single stranded and double stranded DNA during the recombination reaction. The use of a homologous recombination mechanism to repair DNA damage is controlled at several levels, including the binding of Rad51 to single stranded DNA to form the Rad51 nucleofilament, which is controlled through the action of DNA helicases that can counteract nucleofilament formation. Overexpression of Rad51 in different organisms and cell types has a wide assortment of consequences, ranging from increased homologous recombination and increased resistance to DNA damaging agents to disruption of the cell cycle and apoptotic cell death. Rad51 expression is increased in p53-negative cells, and since p53 is often mutated in tumor cells, there is a tendency for Rad51 to be overexpressed in tumor cells, leading to increased resistance to DNA damage and drugs used in chemotherapies. As cells with increased Rad51 levels are more resistant to DNA damage, there is a selection for tumor cells to have higher Rad51 levels. While increased Rad51 can provide drug resistance, it also leads to increased genomic instability and may contribute to carcinogenesis.     

Initial chromosome damage but not DNA damage is greater in ataxia telangiectasia cells.

Cells derived from individuals with ataxia telangiectasia (AT) exhibit increased sensitivity to ionizing radiation and certain drugs (e.g., bleomycin, neocarzinostatin, and etoposide) as evidenced by decreased survival and increased chromosome aberrations at mitosis when compared with normal cell lines. To understand better the basis of this sensitivity, three AT and two normal lymphoblastoid cell lines were fractionated into cell cycle phase-enriched populations by centrifugal elutriation and then examined for their survival and their relative initial levels of DNA damage (neutral DNA filter elution) and chromosome damage (premature chromosome condensation). AT cells exhibited decreased levels of survival in all phases of the cell cycle; however, AT cells in early G1 phase were especially sensitive compared with normal cells in G1 phase. While AT and normal cells exhibited similar levels of initial DNA double-strand breaks in exponential populations as well as throughout the cell cycle, AT cells showed nearly twofold higher initial levels of chromosome damage than normal control cells in G1 and G2 phase. These results suggest that there is a higher rate of conversion of DNA double-strand breaks into chromosome breaks in AT cells, perhaps due to a difference in chromatin organization or stability. Thus one determining component of cellular radiosensitivity might include chromatin structure.     

Effects of 1-β-D-arabinofuranosylcytosine on chromosomes,depending upon the cell cycle stage at the time of exposure

1-β-D-Arabinofuranosyl cytosine (ara-C) is a clinically important cytotoxic drug which is a potent inhibitor of DNA but which has a minimal effect on other cellular processes. The cytotoxic action of ara-C on mammalian cells has been suggested to be due to the chromosome aberrations induced by this compound. Using a marsupial cell line (JU56), the cells of which contain only 9 readily identified chromosomes, the different types of chromosome aberrations induced by a pulse of ara-C have been quantified, and the cell cycle dependence of the damage has been assessed. It was found that, for cells exposed in G₂, both chromatid-type and chromosome-type lesions were produced. The frequency of these lesions was reduced by a chase of deoxycytidine, and there was some evidence that the initial lesions are gaps which may later be converted to true breaks. In early G₂ and late S cells, lesions were produced chiefly at one chromosome locations; this location was not specifically late-replicating. At all stages of S, lesions were chiefly chromatid-type, and some exchanges occurred. The level of damage in S cells was not influences by a deoxycytidine chase. There was negligible damage in cells exposed in G₁.It is suggested that the reason previous investigators have obtained very different cell cycle dependence of chromosomes damage is that the delaying effects of ara-C on cell cycle progression was not taken into account.     

Chromatin condensation and differential sensitivity of mammalian and insect cells to DNA strand breaks induced by bleomycin

Bleomycin (BLM) induces DNA damage in living cells. In this report we analyzed the role of chromatin compactness in the differential response of mosquito (ATC-15) and mammalian (CHO) cells to DNA strand breaks induced by BLM. We used cells unexposed and exposed to sodium butyrate (NaB), which induces chromatin decondensation. By nucleoid sedimentation assay and digestions of nuclei with DNAse I, untreated mosquito cells (no BLM; no NaB) were shown to have more chromatin condensation than untreated CHO cells. By alkaline unwinding ATC-15 cells treated with NaB showed more BLM-induced DNA strand breaks than NaB-untreated CHO cells. The time-course of BLM-induced DNA damage to nuclear DNA was similar for NaB-untreated mammalian and insect cells, but with mosquito cells showing less DNA strand breaks, both at physiological temperatures and at 4 °C. However, when DNA repair was inhibited by low temperatures and chromatin was decondensed by NaB treatments, differences in BLM-induced DNA damage between these cells lines were no longer observed. In both cell lines, NaB did not affect BLM action on cell growth and viability. On the other hand, the low sensitivity of ATC-15 cells to BLM was reflected in their better growth efficiency. These cells exhibited a satisfactory growth at BLM doses that produced a permanent arrest of growth in CHO cells. The data suggest that mosquito cells might have linker DNAs shorter than those of mammalian cells, which would result in the observed both greater chromatin condensation and greater resistance to DNA damage induced by BLM as compared to CHO cells.