J.C. Seegers

The cytotoxic effects of estradiol-17β, catecholestradiols and methoxyestradiols on dividing MCF-7 and HeLa cells

In this study the cytotoxic effects of high concentrations (greater than or equal to 1 x 10(-6) M) of estradiol-17 beta (E2), 2-/4-hydroxyestradiol-17 beta (2-/4-OHE2) and 2-/3-/4-methoxyestradiol-17 beta (2-/3-/4-MeOE2) were determined on dividing MCF-7 and HeLa cells. The 2-MeOE2 metabolite followed by 2-OHE2 and E2 (in this order) proved to be extremely toxic to dividing MCF-7 and HeLa cells. The cytotoxic effect on these cells comprised uneven chromosome distribution. Indirect immunofluorescent studies, in which monoclonal anti-alpha-tubulin antibodies were used, showed that these compounds (2-MeOE2 greater than 2-OHE2 greater than E2) at high concentrations caused abnormal and fragmented polar formations as well as disorientated microtubule arrangement in the dividing MCF-7 and HeLa cells. The 4-OHE2 and 3-/4-MeOE2 metabolites had little or no cytotoxic effects on dividing cells. The large number of abnormal metaphases seen in HeLa cells exposed to 2-MeOE2 suggested that this metabolite may be the ultimate cytotoxic compound. The reduction in the number of HeLa cells with abnormal metaphase configurations after exposure to 2-OHE2 plus quinalizarin (an inhibitor of catechol-O-methyltransferase) indicated that the production of 2-MeOE2 is necessary for the formation of abnormal spindles in metaphase. Quinalizarin treatment in the presence of 2-MeOE2 had no effect on the large number of abnormal metaphases. We therefore conclude that neither E2 nor 2-OHE2, but a high concentration of 2-MeOE2 is responsible for abnormal spindle formation. In additional experiments the number of normal and abnormal dividing HeLa cells were greatly reduced when simultaneously exposed to E2 and 2-/4-hydroxylase-inhibitor alpha-naphthoflavone.

The mammalian metabolite, 2-methoxyestradiol, affects P53 levels and apoptosis induction in transformed cells but not in normal cells.

The endogenous metabolite, 2-methoxyestradiol (2ME), is an inhibitor of tubulin polymerization and is therefore toxic to dividing fast-growing tumor cells. Transformed cells are not equally susceptible to the effects of 2ME. In this study the effects of 1-2 microM doses of 2ME on cell cycle progression, apoptosis induction and on p53 levels were evaluated using flow cytometry in cells with different p53 status. No effect of 2ME was seen in normal human skin fibroblast strain HSF43 with wild-type (wt) p53. However, in SV40 T antigen transformed HSF43 cells (line E8T4), 2ME caused a prominent G2/M arrest, with subsequent micronuclei formation followed by apoptosis. Increased p53 levels were present in the G2/M cells. Our results suggest that 2ME, being a microtubule poison, may release the bound p53 from T antigen, and that this p53 may enhance the apoptotic effects. Two lymphoblast cell lines derived from the same donor, TK6, expressing low levels of wt p53, and WTK1, expressing high levels of mutant p53, showed similar moderate responses to 2ME at 37 degrees C. The effects included enhanced apoptosis and a modest G2/M block. No increase in p53 levels was seen. However, at the permissive temperature of 30 degrees C marked increases in apoptosis and a prominent G2/M-phase block, similar to that seen in the E8T4 cells, were present in the WTK1 cells, indicating that the high levels of mutant p53 have now become functional, enhancing the apoptotic effects initiated by 2ME.

Melatonin has no effect on the growth, morphology or cell cycle of human breast cancer (MCF-7), cervical cancer (HeLa), osteosarcoma (MG-63) or lymphoblastoid (TK6) cells

Melatonin was previously shown to inhibit proliferation of MCF-7 human breast cancer cells. In this study the effect of melatonin on MCF-7 cells was further examined, while human cervical carcinoma (HeLa), osteosarcoma (MG-63) and lymphoblastoid (TK6) cells were tested for the first time. Haemocytometer counts, DNA content, flow cytometry and indirect immunofluorescence for nucleolar proteins, actin and beta-tubulin showed no differences in the growth, cell cycle or morphology between melatonin-exposed and control cells. The direct antiproliferative effect of melatonin thus seems to be confined to a melatonin-responsive subclone of MCF-7 cells and not applicable to the majority of cancer cells.

Effects of gamma-linolenic acid and arachidonic acid on cell cycle progression and apoptosis induction in normal and transformed cells

The effects of arachidonic acid (AA) and gamma-linolenic acid (GLA) on cell cycle progression and apoptosis induction, using flow cytometry, were compared on normal human skin fibroblasts, strain HSF43 with wild type (wt) p53, large T antigen transformed HSF43 cells (line E8T4) with non functional p53, and on two lymphoblast cell lines, TK6 with wt p53 and WTK1 with mutant p53. AA and GLA caused similar dose (50, 75 and 100 microg/ml AA and GLA) and time dependent (24 and 48 h) induction of apoptosis in each cell line. The degrees of the response of the four cell lines were, however, different. The normal HSF43 cells were most resistant against apoptosis induction and the WTK1 cells most susceptible. The apoptosis induction appeared to be independent of functional p53. Cell cycle progression was also similarly affected by AA and GLA in the two cell types. In the fibroblast type cells (HSF43 and E8T4) S- and G2/M-phase arrests were evident after 48 h exposure to AA and GLA, and in the lymphoblast cell lines (TK6 and WTK1) the cells were arrested in the G1-phase.

The effects of chelidonine on tubulin polymerisation, cell cycle progression and selected signal transmission pathways.

Chelidonine is a tertiary benzophenanthridine alkaloid known to cause mitotic arrest and to interact weakly with tubulin. Our interest in chelidonine began when we found it to be a major contaminant of Ukrain, which is a compound reported to be selectively toxic to malignant cells. The effects of chelidonine in two normal (monkey kidney and Hs27), two transformed (Vero and Graham 293) and two malignant (WHCO5 and HeLa) cell lines, were examined. Chelidonine proved to be a weak inhibitor of cell growth, but no evidence for selective cytotoxicity was found in this study. It was confirmed that chelidonine inhibits tubulin polymerisation (IC50 = 24 microM), explaining its ability to disrupt microtubular structure in cells. A G2/M arrest results, which is characterised by abnormal metaphase morphology, increased levels of cyclin B1 and enhanced cdc2 kinase activity. Exposure of all cell lines examined to chelidonine leads to activation of the stress-activated protein kinase/jun kinase pathway (SAPK/JNK).

The induction of apoptosis in human cervical carcinoma (HeLa) cells by gamma-linolenic acid

A high concentration (50 micrograms/ml) of gamma-linolenic acid (GLA) induced morphological lesions typical of apoptosis, as well as DNA fragmentation, in HeLa cells. A lower concentration of GLA (20 micrograms/ml), caused an increased proliferating cell nuclear antigen (PCNA) labelling, with 92.7% cells positive, compared to 27.7% at a concentration of 50 micrograms/ml GLA. In correlation with these results, the number of cells with degraded DNA below the G0/G1 peak increased significantly in the 50 micrograms/ml GLA-treated cells, but increased only slightly in cells exposed to the lower level of GLA. The high levels of PCNA induced by 20 micrograms/ml GLA, in both G1 and S phases, may indicate a state of DNA repair synthesis, whilst at the higher concentration of GLA, most of the cells became apoptotic. Since apoptosis is associated with the deregulation of c-Myc expression, and as the Raf-1-MAP kinase cascade activates the expression of c-Myc and c-Jun, we investigated the effects of 20 and 50 micrograms/ml GLA on the Raf-1, c-Myc and c-Jun levels, and on the activity of MAP kinase. The results showed that 50 micrograms/ml GLA lowered the activity of MAP kinase. As expected with the decreased MAP kinase activity in the cells exposed to the higher level GLA, the c-Jun levels were also lowered. The levels of c-Myc, however, were increased. It is therefore possible that the deregulated expression of c-Myc in the HeLa cells exposed to the high level of GLA (50 micrograms/ml) may contribute to the induction of apoptosis in HeLa cells.

17β-Estradiol metabolites affect some regulators of the MCF-7 cell cycle

The activity of p34(cdc2) plays a key role in the regulation of the eukaryotic cell cycle. Another cell cycle associated molecule is PCNA. We investigated the effects of 2-hydroxy-17beta-estradiol, a cell proliferator, and 2-methoxy-17beta-estradiol, a potent inhibitor of cell growth, on the levels and activity of p34(cdc2) and on the levels of PCNA, as well as on protein phosphorylation in MCF-7 cells. 2-Hydroxyestradiol increased p34(cdc2) activity at G1/S and elevated PCNA levels during S-phase. 2-Methoxyestradiol caused unscheduled activation of p34(cdc2) in S-phase and decreased levels of p34(cdc2) and PCNA during G2/M. We conclude that 2-hydroxy- and 2-methoxyestradiol have definite, though different regulatory functions during the cell cycle.

UkrainTM, a semisynthetic Chelidonium majus alkaloid derivative, acts by inhibition of tubulin polymerization in normal and malignant cell lines

Ukrain(TM) has been described as a semisynthetic Chelidonium majus alkaloid derivative, which exhibits selective toxicity towards malignant cells only. Its mechanism of action has hitherto been uncertain. We found that Ukrain(TM) inhibits tubulin polymerization, leading to impaired microtubule dynamics. This results in activation of the spindle checkpoint and thus a metaphase block. The effects of Ukrain(TM) on the growth, cell cycle progression and morphology of two normal, two transformed and two malignant cell lines did not differ. We could thus find no evidence for the selective cytotoxicity previously reported for Ukrain(TM).

The antimitotic effects of Ukrain™, a Chelidonium majus alkaloid derivative, are reversible in vitro

Ukrain is alleged to be an effective chemotherapeutic drug which causes minimal side-effects as a result of selective toxicity towards malignant cells only. We previously failed to confirm this claim and found Ukrain to be equally toxic to normal, transformed and malignant cell lines by causing a metaphase arrest. In this study we have found the antimitotic actions of Ukrain to be reversible in low doses in vitro, as shown by flow cytometry and concurrent haematoxylin and eosin stains. We hypothesize that the lack of side-effects found in vivo may be due to the lack of therapeutically effective dosages being administered, therefore enabling cells to overcome the metaphase arrest and survive.

Differential cytotoxic effects of gamma-linolenic acid on MG-63 and HeLa cells

Gamma-linolenic acid (GLA) inhibited cell proliferation in MG-63 and HeLa cells. Different morphological lesions were present in dividing cells; abnormal spindle formation in MG-63 cells and chromosome hypercondensation in HeLa cells. Different types of cell death were also present in interphase cells, no apoptosis but only 6% pycnosis in MG-63 cells and 90% apoptosis in HeLa cells. In MG-63 cells immunofluorescence showed segregation of nucleoli components, abnormal spindle formation and decreased labelling of microtubuli during interphase. In HeLa interphase cells prominently labelled abnormally arranged microtubuli were observed. The effects of GLA on protein synthesis in synchronized cells were determined with [35S]-methionine incorporation and SDS-PAGE. Decreased protein synthesis in both G1- and S-phase MG-63 cells was present. In S-phase HeLa cells, proteins of approximately 40, 92 and 150 kD were markedly expressed. Signalling mechanisms involved in cell proliferation and cell death may be differently affected in MG-63 and HeLa cells.