Influence of cinnamaldehyde on UV-induced gene conversion and point mutation in yeast: effect on protein synthesis.

The activity of cinnamaldehyde (CIN), a bioantimutagen in bacterial systems, was tested in the D7 strain of yeast Saccharomyces cerevisiae. Yeast cells were UV-irradiated and post-incubated in liquid growth medium for 2 and 4 h with different concentrations of cinnamaldehyde. During the post-incubation period, DNA-damage-specific functions may be induced. This in turn may affect the genotoxicity and in fact a weak decrease in UV-induced convertant and revertant frequencies was observed after 4 h of post-incubation. The presence of CIN in the growth medium increased the UV-induced gene conversion and reversion. The addition of cycloheximide abolished this effect. To evaluate the CIN effect on protein synthesis, extracts of cells UV-treated and post-incubated for 2 h in the presence of 35S-methionine were performed. SDS-gel electrophoresis demonstrated the inhibitory effect of CIN on a UV-specific protein. This work suggests that CIN might interfere with DNA-damage-inducible systems although it did not exert an antimutagenic activity in our experimental conditions.     

DNA breaks and repair in the mouse leukemia L1210 cells exposed to three different types of interstrand DNA cross-linkers

DNA breaks and repair in mouse leukemia L1210 cells treated with 3 different types of cross-linkers, mitomycin C (MMC), 1-(4-amino-2-methyl-5-pyrimidinyl)-methyl-3-(2-chloroethyl)-3-nitroso ure a hydrochloride (ACNU) and SN-07 (a macromolecular antibiotic), were studied. Measured in D37 values, MMC gave the highest number of cross-links per lethal 'hit' directly after the 1-h treatment in the alkaline elution assay, followed by ACNU and SN-07. A good dose-response increase in induced interstrand DNA cross-linking frequency was observed in cells treated with 2.5-10 micrograms/ml MMC and with 10-100 micrograms/ml ACNU for 1 h with and without 24-h post-incubation. After 6-h post-incubation, the highest frequency of cross-linking was observed in cells treated with 2.5 micrograms/ml MMC and 30 micrograms/ml ACNU, while cross-link production continued in the cells treated with SN-07 for 12-h post-incubation. No significant increase in DNA breaks was observed in cells treated with MMC throughout 24-h post-incubation. The highest frequency of single-strand DNA breaks in cells treated with ACNU was observed immediately after the treatment and they disappeared after 6-h post-incubation. After 24-h post-incubation, a marked enhancement of the DNA breaks was observed in cells treated with SN-07 and the cells contained double-strand DNA breaks also. RNA synthesis was not affected in the cells treated with 10 micrograms/ml MMC and slightly inhibited to 70% of control in those treated with 100 micrograms/ml ACNU, while DNA synthesis in both cells was significantly inhibited after 24-h post-incubation. By contrast, both RNA and DNA synthesis were completely inhibited in cells treated with 8.0 micrograms/ml SN-07.     

Influence of G2 arrest on the cytotoxicity of DNA topoisomerase inhibitors toward human carcinoma cells with different p53 status

We here report the influence of the cell cycle abrogator UCN-01 on RKO human colon carcinoma cells differing in p53 status following exposure to two DNA damaging agents, the topoisomerase inhibitors etoposide and camptothecin. Cells were treated with the two drugs at the IC90 concentration for 24 h followed by post-incubation in drug-free medium. RKO cells expressing wild-type, functional p53 arrested the cell cycle progression in both the G1 and G2 phases of the cell cycle whereas the RKO/E6 cells, which lack functional p53, only arrested in the G2 phase. Growth-arrested cells did not resume proliferation even after prolonged incubation in drug-free medium (up to 96 h). To evaluate the importance of the cell cycle arrest on cellular survival, a non-toxic dose of UCN-01 (100 nM) was added to the growth-arrested cells. The addition of UCN-01 was accompanied by mitotic entry as revealed by the appearance of condensed chromatin and the MPM-2 phosphoepitope, which is characteristic for mitotic cells. G2 exit and mitotic transit was accompanied by a rapid activation of caspase-3 and apoptotic cell death. The influence of UCN-01 on the long-term cytotoxic effects of the two drugs was also determined. Unexpectedly, abrogation of the G2 arrest had no influence on the overall cytotoxicity of either drug. In contrast, addition of UCN-01 to cisplatin-treated RKO and RKO/E6 cells greatly increased the cytotoxic effects of the alkylating agent. These results strongly suggest that even prolonged cell cycle arrest in the G2 phase of the cell cycle is not necessarily coupled to efficient DNA repair and enhanced cellular survival as generally believed.     

Protective role of potentially lethal damage repair in the neoplastic transformation of Balb/c 3T3 cells treated with N-methyl-N'-nitro-N-nitrosoguanidine

To determine the role of repair of potentially lethal damage (PLD) in the initiation process of neoplastic transformation, Balb/c 3T3 cells treated with N-methyl-N'-nitro-N-nitrosoguanidine (MNNG) were temporarily exposed to conditioned medium obtained from density-inhibited Chinese hamster cell cultures, as a post-treatment for the induction of PLD repair. With or without this exposure, cell survival and transformation frequencies were simultaneously determined by colony-formation and focus-formation assays, respectively. Temporary exposure to conditioned medium resulted in a 20-30% increase in cell survival compared with no exposure. Post-treatment with conditioned medium resulted in a 60-65% reduction in transformation frequencies. At the molecular level, the repair of MNNG-induced single-strand breaks of DNA occurred much more rapidly in conditioned medium. These data suggest that PLD repair reduces the in vitro neoplastic transformation through excision repair operative during the cessation of DNA replication. Thus, PLD repair appears to be preventive against neoplastic fixation in initiation of neoplastic development.     

The relationship between molecular and cellular repair from potentially lethal damage induced by N-methyl-N'-nitro-N-nitrosoguanidine in Chinese hamster V79 cells

The relationship between molecular and cellular repair from potentially lethal damage (PLD) induced by N-methyl-N'-nitro-N-nitrosoguanidine (MNNG) was investigated in exponentially growing V79 Chinese hamster cells. We compared the repair processes by an alkaline sucrose sedimentation analysis and a colony formation assay. MNNG-treated cells were exposed to the conditioned medium (CM) from density-inhibited plateau-phase V79 cell cultures, as a post-treatment for the induction of PLD repair. When MNNG-treated cells were postincubated in CM, cell survival continuously increased for 18 h, and during this period, DNA replication was substantially suppressed. CM did not inhibit the rejoining of the single-strand breaks of parental DNA. Rather, parental DNA fragments sedimented more rapidly when postincubated in CM than in fresh medium. These data indicate that cellular recovery from MNNG-induced PLD increases in proportion to the resealing of MNNG-induced single-strand breaks of DNA during the suppression of DNA replication, suggesting that excision repair is involved in the PLD repair process.     

Enhancement of excision-repair efficiency by conditioned medium from density-inhibited cultures in V79 Chinese hamster cells: Evidence for excision repair as an error-free repair process

Conditioned medium from density-inhibited V79 Chinese hamster cell cultures, given as a post-treatment to UV-irradiated homologous cells, was demonstrated to reduce the lethal action of ultraviolet light by temporarily blocking DNA replication. Since the increased survival was not affected by various nontoxic concentrations of caffeine, such protective effect would be attributable to the prolonged intervention of excision repair before DNA replication during the post-treatment period. The influence of conditioned medium on the UV-induced mutation at the ouabain-resistance locus was also examined and a significant decrease in mutation frequency was noted. The observed reduction in killing and mutation as a result of post-incubation in conditioned medium, which delays DNA replication, would be interpreted as evidence that conditioned medium provides a longer period of time for an error-free excision-repair process, leaving lesion in DNA available for error-prone post-replication repair.     

2,3-Butanedione monoxime does not protect cardiomyocytes under oxidative stress

Heart muscle ischemia-reperfusion provokes a pronounced cardiomyocyte oxidative stress. In the present study, we examined a possible protective effect of the cardioprotective drug, 2,3-butanedione monoxime (BDM), on the cultured neonatal cardiac myocytes exposed to oxidative stress induced by hypochlorous acid (HOCl), that may be formed by activated polymorphonuclear neutrophils in myocardium ischemic-reperfusion areas, and a useful model oxidant, tert-butyl hydroperoxide (tBHP). Using isolated rat cardiomyocytes substantial cytotoxicity of HOCl and tBHP was demonstrated: The concentrations of HOCl and tBHP causing a 50% decrease of cardiomyocyte cell viability were estimated to be 55 +/- 5 microM and 36 +/- 6 microM, respectively. The cell viability measured immediately after the tBHP oxidative treatment was significantly higher than that measured after 22 h of cell post-incubation in a fresh culture medium. This showed delayed cell death after removing tBHP. Hypochlorous acid treatment of cardiomyocytes did not change cellular viability during the cellular post-incubation in a fresh medium. Even a long-term (22 h) incubation of oxidatively damaged cardiomyocytes with BDM (5 mM) added after the HOCl removal did not recover the viability of the HOCl-exposed cells. In the presence of BDM, the cytotoxicity of HOCl significantly increased probably due to a direct reaction of both compounds and toxic chlorinated derivative formation. 2,3-Butanedione monoxime (5 mM) did not reduce cytotoxicity of tBHP, either. Such well-known antioxidative agents as melatonin or glutathione considerably prevented oxidant-induced cell death in a concentration-dependent manner.     

Difference in O6-methylguanine methyltransferase activity among transformed NIH3T3 cell clones

We examined the sensitivity to the lethal effects of methylating agents and the O6-methylguanine methyltransferase (MTR) activities of in vitro transformed NIH3T3 cell clones. The sensitivities to the lethal effects of MNNG were not different among all 49 transformed cell clones examined and do not correlate with the MTR activities. All 8 spontaneously transformed cell clones showed the same sensitivities to ACNU as the parental cell line. 2 of 20 transformants induced by UV or MNNG showed higher sensitivities to the ACNU although the MTR activity was normal. One cell clone transformed by UV was sensitive to ACNU and showed about half MTR activity. 5 of 19 cell clones transformed by oncogenes (Ha-ras or SV40 ori-) were sensitive to the lethal effects of ACNU and showed the low MTR activities, but were not as much sensitive as a Ha-MuSV transformed cell clone, Ha821.     

Clonal analysis of vertebrate myogenesis: IV. Medium-dependent classification of colony-forming cells

The cell lineage of chick leg muscle between 3 and 12 days of development has been studied by use of an in vitro clonal assay. The assay permits distinctions to be made among various types of muscle-colony-forming cells (MCF cells) on the basis of their medium requirements and clonal morphology. Results suggest the sequential occurrence of at least four types of MCF cells, three of which require conditioned medium for their differentiation and one of which can form differentiated colonies in fresh medium.The nature of the “conditioned medium effect” was further investigated by the use of medium-switch experiments. By this process it was shown that the same populations of colony-forming cells attach and grow in fresh and conditioned medium and that the differentiation of colonies derived from conditioned-medium-requiring myoblasts is permitted by brief exposure to conditioned medium followed by culture in fresh medium. Further investigation indicated that during brief exposure to conditioned medium the gelatin-coated petri plate surface is altered such that differentiation of conditioned-medium-requiring colonies is allowed. We conclude that the conditioned medium effect involves a surface-mediated interaction between myoblasts and one or more conditioned medium components.     

Lethal and mutagenic actions of N-methyl-N'-nitro-N-nitrosoguanidine potentiated by oxidized glutathione, a seemingly harmless substance in the cellular environment.

Both the lethal and the mutagenic actions of N-methyl-N'-nitro-N-nitrosoguanidine (MNNG) on cells of Streptococcus pneumoniae were greatly potentiated by a component of yeast extract added to the cellular environment. This component was found to be an oxidation product of glutathione, glutathione disulfide (GSSG). At low concentrations in the medium, both GSSG and glutathione potentiated MNNG action, but at high concentrations, glutathione (and other sulfhydryl compounds) abolished the effect. Point mutations in a cellular gene conferred resistance to the potentiating effect, and they blocked uptake of either GSSG or glutathione into the cells as well. This gene apparently encodes a component of the system for glutathione transport in S. pneumoniae. The mechanism by which GSSG, an apparently innocuous substance in the environment, renders low levels of MNNG genotoxic and cytotoxic thus depends on its transport into the cell, where it is reduced by glutathione reductase and then activates intracellular MNNG. Also, it was observed that mutants of S. pneumoniae defective in DNA mismatch repair are more resistant to MNNG than are wild-type cells by a factor of 2.5.     

Genetic analysis of the 5-azacytidine sensitivity of Escherichia coli K-12.

DNA containing 5-azacytidine (5-azaC) has been shown to form stable detergent-resistant complexes with cytosine methylases. We reasoned that if 5-azaC treatment causes protein-DNA cross-links in vivo, then mutations in DNA repair and recombination genes may increase the sensitivity of a cell to 5-azaC. We found that although recA (defective) and lexA (induction-negative) mutants of Escherichia coli were very sensitive to the drug, mutations in uvrA and ung genes had little effect on cell lethality. The sensitivity of recA strains to 5-azaC was dose dependent and was enhanced by the overproduction of a DNA cytosine methylase in the cell. Unexpectedly, a strain of E. coli carrying a recA mutation and a deletion of the DNA cytosine methylase gene (dcm) was found to be significantly sensitive to 5-azaC. Study of mutations in the pyrimidine salvage pathway of E. coli suggests that direct phosphorylation of 5-azaC, rather than phosphorylation of its degradation products, is largely responsible for the lethal effects of the drug. The addition of uracil to the growth medium has little effect on cell lethality of recA mutants, but it partially reversed the inhibition of cell growth caused by 5-azaC. This reversal of the bacteriostatic effects of the drug could not be achieved by adding cytosine or orotic acid to the growth medium and required the presence of functional UMP-pyrophosphorylase (gene upp) in the cell.     

The effect of thioredoxin on the radiosensitivity of bacteria

The ability of Escherichia coli thioredoxin to protect cells from lethal amounts of gamma radiation was tested using bacterial strains engineered to contain different amounts of thioredoxin per cell. Cells grown to late stationary phase demonstrated a decreasing sensitivity to gamma-radiation with increasing amounts of thioredoxin per cell. Exponentially growing cells were equally sensitive to the gamma-radiation regardless of the intracellular concentration of thioredoxin. Cells exhibiting the radiation-resistant phenotype in the stationary phase reverted to the radiation-sensitive phenotype when diluted into fresh growth medium. These results suggest that thioredoxin can protect cells from gamma-radiation under certain metabolic conditions.     

Lethal effects of fluorodeoxyuridine on cultured mammalian cells at various stages of the cell cycle

The lethal damage induced by the exposure of synchronized Chinese hamster cells to various concentrations of 5-fluoro-2′deoxyuridine (FUdR) was not selectively restricted to cells exposed during the period of DNA synthesis S. The colony survival fraction observed after treatment for one hour with 5 × 10^?5 M FUdR was very low (0.0001–0.0003) whether the drug was administered during early G₁, late G₁, early S or in middle S. The survival of cells treated with the same concentration of FUdR during mitosis, however, was significantly higher (0.62) showing that mitotic cells were less sensitive to FUdR. Administration of 10^?7M thymidine or “conditioned” medium for one hour reversed the lethal effect of FUdR or improved the survival, depending on the time after removal of the FUdR at which these substances were given.     

Chemical oncogenesis in cultured mouse embryo cells in relation to the cell cycle.

Using the C3H/10T 1/2 CL8 line of mouse embryo fibroblasts and three different methods of obtaining cell cycle synchrony, namely arginine or isoleucine deficiency and release from postconfluence inhibition of growth, a sensitive phase for oncogenic transformation induced by N-methyl-N'-nitro-N-nitrosoguanidine (MNNG) has been found. This sensitive phase is located somewhere between the G1/S boundary and a point 4 hr prior to this marker. Methylation of cellular macromolecules by tritiated MNNG is not cycle-dependent in cells synchronized by arginine deficiency. The capacity of cells to repair DNA single strand breaks produced by MNNG was examined by alkaline sucrose sedimentation analysis in cells synchronized by arginine deficiency and treated with MNNG during phases of the cell cycle sensitive and insensitive to oncogenic transformation. Whereas DNA repair was found to be equally rapid in cells treated just before S phase (I), or just after commencement of DNA synthesis (III), transformation was maximal in I. By contrast, cells treated when blocked by arginine deficiency (II) repaired DNA slowly and were not sensitive to malignant transformation. Cells in I and II, which repaired DNA at very different rates, were equally sensitive to MNNG-induced lethality, while cells in III, which repaired DNA at the same rate as cells in I, suffered greater lethality. Thus, in this system it was concluded that there was no direct correlation between DNA repair, as measured by alkaline sucrose sedimentation analysis of prelabeled DNA, and malignant transformation or lethality produced by MNNG. In preliminary experiments malignant transformation induced by cytosine arabinoside (1-beta-D-arabinofuranosylcytosine, ara-C) has been found to occur mainly in S phase, indicating that diverse chemical oncogens may have different sites of action, or that activation of chemical oncogens is cell cycle-specific for some agents.     

Low tumor cell density environment yields survival advantage of tumor cells exposed to MTX in vitro

Stable resistance to methotrexate has been well characterized after prolonged treatment of the HT-29 colon cancer cell line, but the mechanism of cell survival at the early stages of the drug resistance process still remains unclear. Here, we demonstrate that human cancer cells in vitro are sensitive to methotrexate only above a critical cell culture density, which specifically coincides with their ability to deplete the extracellular nucleosides from a fully supplemented culture medium. At lower cell densities, extracellular nucleosides remain intact and allow salvage nucleotide synthesis that renders cells insensitive to the drug. Consistently, medium conditioned by cells seeded at standard cell densities sensitizes low cell density cultures. Extracellular nucleosides are the determinants of sensitivity because the latter effect can be mimicked with the use of inhibitors of nucleoside cellular import and reversed by supplying exogenous thymidine and hypoxanthine. Interestingly, treatment at a sensitizing cell density does not preclude the survival of less than 1% of the cells--which have no intrinsic resistance--owing to the inability of the dying cell population to condition the culture medium; this population thus survives indefinitely to continuous treatment by keeping adapted to a low cell number. This cell density-dependent adaptive process accounts for the initial steps of in vitro resistance to methotrexate (MTX) and provides a novel mechanistic insight into the cell population dynamics of cell survival and cell death during drug treatment.     

Recovery from exposure to DNA-damaging chemicals in radiation-resistant insect cells

Radioresistant TN-368 lepidopteran insect cells were examined with respect to their sensitivity to the chemical agents methyl methanesulfonate (MMS), N-methyl-N'-nitro-N-nitrosoguanidine (MNNG), propane sultone (PS), mitomycin C (MMC), and 4-nitroquinoline 1-oxide (4NQO). Based on survival ability, the TN-368 cells were more resistant than most mammalian cells to each of these agents. Concentrations of these agents which reduce survival to about 10% were used to assess recovery ability assayed by colony formation in liquid-holding and split-dose experiments. Liquid-holding experiments were performed by exposing cells in the plateau phase of growth for 1 h to 8 mM MMS, 50 microM MNNG, 9 mM PS, 110 microM MMC, or 175 microM 4NQO, removing the drug and incubating cells in spent medium for 6 h, and plating for colony formation. Split-dose experiments were performed by exposing exponentially growing cells to the above drug concentrations for 1 h, incubating in fresh medium for 6 h, exposing the cells to the agent for an additional hour, and plating. The TN-368 cells were able to significantly recover from MMS, MNNG and PS in both types of experiment. Recovery from 4NQO was observed in liquid-holding experiments and not assessed in split-dose experiments. In all cases where recovery was observed, survival enhancement was approximately 2-fold. Recovery from MMC (a cross-linking agent) exposure was not observed in either type of experiment. In addition, recovery from 8-methoxypsoralen plus UVA light (PUVA), another cross-linking treatment, was not observed. These studies indicate that DNA-DNA and/or DNA-protein crosslinking may be important molecular lesions causing death in the lepidopteran cells and that these cells may have some difficulty in repairing such damage.     

Adaptive repair of cross-links in DNA of Micrococcus radiodurans

Cross-links in the DNA of Micrococcus radiodurans induced by mitomycin C were repaired during post-incubation. This repair process was inhibited in cells post-incubated in the presence of chloramphenicol. However, the removal of cross-links in DNA was almost normal, even in the presence of chloramphenicol, if the cells were pretreated with lower concentrations of mitomycin C.     

Exogenous O6-methylguanine inhibits adduct removal and sensitizes human cells to killing by the chemical carcinogen N-methyl-N'-nitro-N-nitrosoguanidine

We partially depleted the O6-methylguanine-DNA methyltransferase activity in four O6-methylguanine (O6-mGua) repair-proficient (Mer+) human cell strains with exogenous O6-mGua (2 mM for 3 h, a non-toxic regimen) and then challenged them with N-methyl-N'-nitro-N-nitrosoguanidine (MNNG). MT-partially depleted HT29 cells removed O6-mGua from DNA at about half the rate of control cells, while removal of 3-methyladenine was unaffected. In spite of partial depletion of MT, however, cell killing by MNNG in a colony-forming assay with HT29, A549, A498 or KD cells was not greatly affected. (This is in contrast to the dramatic potentiation of CNU cytotoxicity observed previously.) In an attempt to sensitize Mer+ strains to killing by MNNG, we treated cells with O6-mGua following MNNG exposure (0.4 mM for 4 days), in addition to the pre-MNNG treatment of 2 mM O6-mGua for 3 h. This sensitized KD and HT29 cells 2-fold to killing by MNNG, based on the dose at 10% survival, but did not sensitive Mer- A1336. However, post-treatment alone was as effective as combined pre- and post-treatment in sensitizing KD cells to killing. Thus, when the O6-mGua post-treatment was begun, greater than 50% of O6-mGua was already removed from cell DNA. Our findings may be accounted for by at least two schemes, one in which nonlethal O6-mGua are removed from DNA rapidly, while potentially lethal O6-mGua are repaired later. The other scheme proposes that exogenous O6-mGua increases the lethality of a non-O6-mGua lesion by reducing its repair both in Mer+ and Mer- cells. Both schemes are consistent with the hypothesis that O6-mGua may be a lethal DNA lesion in human cells.     

Peroxynitrite promotes mitochondrial permeability transition-dependent rapid U937 cell necrosis: Survivors proliferate with kinetics superimposable on those of untreated cells

A short term exposure to peroxynitrite promotes a time- and concentration-dependent lethal response in U937 cells. The mode of cell death was necrosis and rapid (within minutes) cell lysis was found to occur via a mechanism involving mitochondrial permeability transition. Apoptosis was not detected in cells exposed to low levels of peroxynitrite, or in cells which survived a treatment with toxic amounts of peroxynitrite, neither after the 60 min exposure nor following increasing time intervals of growth in fresh culture medium. Rather, cells treated with peroxynitrite concentrations which were not immediately lethal, as well as the survivors of treatments with toxic levels of peroxynitrite, proliferated with kinetics superimposable on those observed in untreated cells.     

Peroxynitrite promotes mitochondrial permeability transition-dependent rapid U937 cell necrosis: survivors proliferate with kinetics superimposable on those of untreated cells

A short term exposure to peroxynitrite promotes a time- and concentration-dependent lethal response in U937 cells. The mode of cell death was necrosis and rapid (within minutes) cell lysis was found to occur via a mechanism involving mitochondrial permeability transition. Apoptosis was not detected in cells exposed to low levels of peroxynitrite, or in cells which survived a treatment with toxic amounts of peroxynitrite, neither after the 60 min exposure nor following increasing time intervals of growth in fresh culture medium. Rather, cells treated with peroxynitrite concentrations which were not immediately lethal, as well as the survivors of treatments with toxic levels of peroxynitrite, proliferated with kinetics superimposable on those observed in untreated cells.