Olen E. Domon

p53, mutations, and apoptosis in genistein-exposed human lymphoblastoid cells.

The phytoestrogen, genistein, is a naturally occurring isoflavone found in soy products. On a biochemical basis, genistein is a competitive inhibitor of tyrosine kinases and the DNA synthesis-related enzyme, topoisomerase-II (topo-II). Exposure of mammalian cells to genistein results in DNA damage that is similar to that induced by the topo-II inhibitor and chromosomal mutagen, m-amsa. In order to determine the potential genotoxicity of genistein, human lymphoblastoid cells which differ in the functional status of the tumor suppressor gene, p53, were exposed to genistein and the induction of micronuclei quantified by microscopic analysis. In addition, the mutant fraction at the thymidine kinase (tk) locus (both the normal-growth and slow-growth phenotypes) was determined by resistance to trifluorothymidine (TFT) and at the hypoxanthine phosphoribosyl transferase (hprt) locus by resistance to 6-thioguanine (6-TG). Flow cytometric analysis of the percentage of viable, apoptotic and degenerating cells was utilized to determine the rate and kinetics of cell death after genistein exposure. The detection of micronuclei in both cell lines indicated that genistein-induced damage had occurred in both AHH-1 tk+/- and L3. Linear regression analysis detected a significant increase in the number of 6-TG-resistant clones in both AHH-1 tk+/- (p53+/-) and L3 (p53+/+). A comparison of slopes revealed no difference between the lines. In contrast, a significant, concentration-dependent increase in the number of TFT-resistant clones with the slow-growth phenotype was detected in AHH-1 tk+/- (mutant p53), but not in L3 (wild-type p53). Cell death occurred primarily by apoptosis in both cell lines; however, a concentration-dependent decrease in the percentage of viable cells was detected immediately after exposure in L3, but not until 32 h after exposure in AHH-1 tk+/-. A comparison of the slopes of the concentration-response curves for the percentage of viable cells revealed no difference between the cell lines in the effect of genistein on cell viability. Our results may be interpreted that genistein is a chromosomal mutagen and that p53 functional status affects the recovery of chromosomal mutants, possibly by signalling cells into the apoptosis pathways.

Programmed cell death and mutation induction in AHH-1 human lymphoblastoid cells exposed to m-amsa

One role of programmed cell death (apoptosis) is the removal of cells with DNA damage from the population. Certain cells, however, are able to suppress the signals for apoptotic cell death and maintain viability. This suggests that the susceptibility of a cell to either undergo apoptosis or escape from the apoptotic death pathways may be an important factor in chemical mutagenesis. In order to provide insight into the role of apoptosis in the recovery of chemically induced mutants, AHH-1 cells were exposed to the chromosomal mutagen, m-amsa, and the percentage of cells undergoing apoptosis or necrosis quantified by flow cytometry. Logistic regression analysis revealed that the primary manner of cell death was by apoptosis. Two specific-locus mutations assays, the tk and the hprt, were utilized as markers for cells with DNA damage and that retained clonogenicity under conditions known to induce apoptosis. Analysis of variance indicated that the concentration-dependent increase in the mutant fraction at the tk locus was significant and the result of the recovery of clones with the slow-growth phenotype. Because this phenotype is thought to reflect chromosomal mutations, these results are consistent with the survival and clonogenicity of damaged cells. This suggests that the ability to recover mutant cells may be influenced by the suppression of or an escape from the apoptotic death pathways.

Modulation of SCE induction and cell proliferation by 2-mercaptoethanol in phytohemagglutinin-stimulated rat lymphocytes.

Abstract2-Mercaptoethanol (2-ME) is used as a medium supplement to enhance the proliferation of lymphocytes culturedin vitro. In this study, we have examined the effects of 2-ME on cell growth and on SCE induction in cultures of unstimulated and phytohemagglutinin (PHA)-stimulated Fischer 344 rat lymphocytes. There were virtually no metaphases detected in cells cultured without PHA. In PHA-stimulated cultures, 2-ME decreased SCE-frequency but it enhanced SCE frequency in the presence of S to 12.5 µM bromodeoxyuridine (BRd U). Both mitotic and replication indices were increased in the PHA/2-ME system. The levels of incorporated exogenous thymidine, in the presence of 2-ME, were relatively low in unstimulated cells, suggesting that 2-ME is not mitogenic for T-cells. However, 2-ME enhanced PHA-induced response of T-cells as evidenced by increased levels of thymidine incorporation into cellular DNA. The growth promoting effects and the decrease in SCE frequency caused by 2-ME upon PHA stimulation indicate that 2-ME may alter the nature of interaction between PHA and cellular activating properties or the replicative processes.

A role for apoptosis in the toxicity and mutagenicity of bleomycin in AHH-1 tk+/− human lymphoblastoid cells

The chromosomal mutagen, bleomycin, is also noted for its toxic properties, although the mechanism of cell death is not fully understood. In order to determine if cell death occurred by apoptosis or necrosis, AHH-1 tk+/- cells were exposed to bleomycin and the percentage of viable, apoptotic and necrotic cells quantified by flow cytometry. Logistic regression analysis indicated that the primary manner of cell death was through the apoptosis pathways, that apoptosis was delayed, and that apoptosis was accompanied by an arrest in the G2 phase of the cell cycle. Once apoptosis was established as a mechanism for cell death, the efficiency with which these pathways removed damaged cells from the population was evaluated with the use of specific-locus mutation assays (tk and hprt) as indicators of cells with DNA damage that maintained viability and clonogenicity. Linear regression analysis detected a significant, concentration-dependent increase in the numbers of TFTr clones with the slow-growth phenotype. This suggests that a proportion of cells with bleomycin-induced DNA damage did not undergo cell death by apoptosis and that apoptosis, a mechanism for the destruction of damaged cells, is not fully efficient in the AHH-1 tk +/- cell line.

The role of programmed cell death in the toxicity of the mutagens, ethyl methanesulfonate and N-ethyl-N'-nitrosourea, in AHH-1 human lymphoblastoid cells

In order to determine the pathway for cell death in alkylating agent-exposed human lymphoblastoid cells, AHH-1 cells were exposed to either ethyl methanesulfonate (EMS) or ethyl nitrosourea (ENU) and the effect on relative cell growth and plating efficiency quantified. Flow cytometric (FCM) assays were utilized to quantify cell viability and to determine if cell death occurred through necrosis or apoptosis. As expected, exposure to the simple ethylating agents resulted in concentration-dependent decreases in plating efficiencies at each time interval after exposure (Days 0, 2, 3 and 7). EMS exposure did not significantly affect the relative cell growth, in contrast to ENU exposure, which inhibited cell growth. The FCM viability assay, based on light scatter characteristics, revealed that exposure to either alkylating agent resulted in a significant reduction in the percentage of viable cells. The results of the FCM dye-exclusion assays revealed that while necrosis occurred in EMS- and ENU-exposed cells, the primary manner of cell death was apoptosis. AHH-1 cells were stained with propidium iodide and fluorescein diacetate, the population of cells sorted electronically and the cell type (necrotic, apoptotic or viable) confirmed morphologically. Our results clearly indicate that exposure to EMS or ENU results in the movement of AHH-1 cells into the pathway for apoptosis and cell death.

Evaluation of the genotoxicity of the phytoestrogen, coumestrol, in AHH-1 TK(+/-) human lymphoblastoid cells.

Coumestrol, a phytoestrogen found in high levels in alfalfa and red clover, is of concern since endocrine disorders have been observed in farm animals exposed to high levels of phytoestrogens. Previous studies found that coumestrol was an effective inducer of DNA strand breaks, micronuclei, and mutations in the Hypoxanthine phosphoribosyl transferase (HPRT) gene of Chinese hamster ovary cells. In the experiments presented here, we extended the previous studies to examine the effect of coumestrol exposure on AHH-1 TK(+/-) human lymphoblastoid cells. Micronuclei were induced with the highest frequency occurring at day 2 after exposure. Flow cytometric analysis of annexin V-FITC-7-aminoactinomycin D stained cells indicated that the primary pathway of cell death was by apoptosis. Mutations were induced in the Thymidine Kinase (TK) gene and were due primarily to the induction of clones with the slow-growth phenotype. Subsequent molecular analysis revealed the loss of exon 4 in the coumestrol-induced clones, indicative of loss-of heterozygosity and consistent with a proposed inhibition of topoisomerase-II activity as a mechanism of action for coumestrol. Taken together, these results suggest that coumestrol exhibits both mutagenic and clastogenic properties in cultured human lymphoblastoid cells.

Cell cycle traverse in AHH-1 tk +/- human lymphoblastoid cells exposed to the chromosomal mutagen, m-Amsa

AHH‐l tk +/− cells were exposed to the chemotherapeutic agent, m‐amsa, both in complete medium and in medium without serum, subcultured in complete medium, and the effect on the traverse of the cell cycle determined by flow cytometric analysis of bromodeoxyuridine (BrdUrd)‐labeled DNA. After exposure to m‐amsa (day 0), the percentage of S‐phase cells increased significantly (P < 0.0017) with increasing concentration. Cells also accumulated in G2/M as evidenced by the significant (P < 0.0026), concentration‐dependent increase in the percentage of cells detected within this phase. Serum deprivation during exposure resulted in significantly (P = 0.024) more cells in S‐phase than in cultures exposed to m‐amsa in complete medium. After three days in culture, a significant (P = 0.0001) accumulation of cells in G2/M was present; the percentage of cells in G2/M did not differ significantly (P = 0.148) in cultures exposed to m‐amsa in complete medium or in serum‐free medium. However, a significant (P < 0.001) loss of S‐phase cells was found in cultures exposed without serum. At day 7, no significant concentration effects were detected (G0/G1, P = 0.6026; S‐phase, P = 0.9773; G2/M, P = 0.8401). These results demonstrate that exposure to m‐amsa perturbs the traverse of the cell cycle, initially by inhibiting the completion of S‐phase and followed by an accumulation of cells in G2/M. In addition, exposure to m‐amsa under conditions of serum deprivation results in an increased percentage of cells in the initial S‐phase after exposure, the loss of S‐phase cells from the culture after three days, and the appearance of a subdiploid peak, consistent with cells undergoing apoptosis.

Dominant lethal test response with IMS and TEM using different combinations of male and female stocks of mice

We conducted dominant lethal studies with chemical mutagens IMS and TEM to investigate the influence which different treated male stocks might have upon individual female response. In both studies, treated males from a CD-1 random bred stock and each of two F1 hybrid stocks (C57BL/6N X C3H; C57BL/6J X BALB/c) were mated to untreated females from the two F1 hybrid stocks. We found that variation in response due to the treatment effect was modulated by the specific male stock/female stock combination involved. The male-dependent variation observed prevented any meaningful evaluation of relative female stock sensitivity but it was obvious that factors other than differences in repair capacity of female germ cells contributed to the response differences observed.

Sister chromatid exchange frequency, cellular replication and relative cloning efficiency in human teratocarcinoma-derived cells

To determine the relationships between the induction of specific biological responses and exposure to DNA-damaging agents, human teratocarcinoma-derived cells were exposed to either ethyl methanesulfonate or to methyl methanesulfonate, and sister chromatid exchange, cellular proliferation and relative cloning ability measured. SCE increased while cellular proliferation and relative cloning ability each decreased in a concentration-dependent manner. Methyl methanesulfonate was consistently more efficient in inducing biological responses than was ethyl methanesulfonate. When the individual responses were compared, the decrease in cellular proliferation paralleled the reduction in cloning efficiency. A strong correlation was also observed between the reduction in relative cloning ability and sister chromatid exchange frequency. Because these relationships are similar to those previously described in other mammalian cell lines, the observations in our study suggest that the P3 cell line is an appropriate choice for modeling effects of toxicant exposure in human cells.

Effect of bromodeoxyuridine on the proliferation and growth of ethyl methanesulfonate-exposed P3 cells: Relationship to the induction of sister-chromatid exchanges

Although sister-chromatid exchange (SCE) analysis is recognized as an indicator of exposure to DNA-damaging agents, the results of these analyses have been confounded by the use of bromodeoxyuridine (BrdUrd) to differentially label the sister chromatids. Not only does BrdUrd itself induce SCE, it also modulates the frequency of SCE induced by certain DNA-damaging agents. In order to examine this effect of BrdUrd on SCE frequency, an indirect method which lends itself to measurements both with and without BrdUrd was employed. Human teratocarcinoma-derived (P3) cells were exposed to ethyl methanesulfonate (EMS) and cultured with increasing concentrations of BrdUrd for lengths of time corresponding to one, two, and three generations of cell growth. At each time point, the distribution of nuclei among the phases of the cell-cycle and cell growth were evaluated for each concentration and chemical. A statistical model was employed which tested both for the main effects of chemicals and culture times and for interactions between these factors. Both EMS and BrdUrd significantly affected the percentages of nuclei within the cell-cycle. Exposure to EMS resulted in decreases in the percentages of nuclei in G0 + G1 and increases in the G2 + M compartment. Exposure to BrdUrd affected the size of the G0 + G1 compartment as well as the percentage of S-phase nuclei. Cell growth was reduced as a consequence of increasing EMS concentration and as a function of BrdUrd concentration; the effects of these chemicals were more readily apparent at the later time points. Most importantly, for both the cell-cycle kinetics data and the cell growth data, no evidence of an interaction between the effects of EMS and the effects of BrdUrd was detected statistically. These results may be interpreted to mean that while both EMS and BrdUrd affect the induction of SCE, under the conditions of this experiment, the effects are additive rather than interactive.