Sodium butyrate induces G2 arrest in the human breast cancer cells MDA-MB-231 and renders them competent for DNA rereplication.

When exposed to sodium butyrate (NaBut), exponentially growing cells accumulate in G1 and G2 phases of the cell cycle. In the human breast cancer cell line MDA-MB-231, an arrest in G2 phase was observed when the cells were released from hydroxyurea block (G1/S interface) in the presence of NaBut. The inhibition of G2 progression was correlated with increased contents both of total p21(Waf1) and of p21(Waf1) associated with cyclin A and with an inhibition of cyclin A- and B1-associated histone H1 kinase activities measured in cell lysates, as well as with dephosphorylation of the RB protein. A decrease in the cell contents of cyclins A and B1 was also observed but this decrease was preceded by p21(Waf1) accumulation. When NaBut was removed from the culture medium of cells blocked in G2 phase, p21(Waf1) level decreased and, instead of proceeding to mitosis, these cells resumed a progression toward DNA rereplication. These results suggest that the induction of p21(Waf1) by NaBut leads to the inhibition of the sequential activation of cyclin A- and B1-dependent kinases in this cell line, resulting in the inhibition of G2 progression and rendering the cells competent for a new cell division cycle.

Antitumor activity of oxaliplatin in combination with 5-fluorouracil and the thymidylate synthase inhibitor AG337 in human colon, breast and ovarian cancers.

Oxaliplatin, classical [5-fluorouracil (5-FU)] and non-classical (AG337) thymidylate synthase inhibitors have shown promising activity in the treatment of cancer. This study investigates the cytotoxic effects of oxaliplatin in combination with 5-FU and AG337 in cultured human colon (HT29, CaCo2), breast (MCF-7, MDA-MB-231) and ovarian (2008) cancer cell lines, and their derived counterparts selected for their resistance to 5-FU (HT29-5-FU), doxorubicin (MCF-7mdr) or cisplatin (2008C13). Therapeutic experiments were conducted in mice bearing colon-HT29 xenografts and in the GR hormone-independent mammary carcinoma model. In vitro, oxaliplatin shows potent cytotoxic activity in colon (IC50 from 2.1 +/- 1.1 to 5.9 +/- 1.7 microM), ovarian (IC50 = 10 +/- 1.6 microM) and breast cancer cells (IC50 from 7.4 +/- 2.7 to 17.9 +/- 7.1 microM). Oxaliplatin was a potent inhibitor of DNA synthesis and bound to cellular DNA. Surprisingly, the overall amount of oxaliplatin DNA binding was significantly inferior to that induced by isocytotoxic concentrations of cisplatin in HT29 (p=0.026). In vitro, synergistic antiproliferative effects were observed when oxaliplatin was added to 5-FU and AG337. Those synergistic effects of combinations were maintained in colon HT29-5-FU cancer cells. In vivo, 5-FU increased significantly the antitumor activity of oxaliplatin in HT29 xenografts (p=0.0036), and similarly 5-FU and AG337 increased the activity of oxaliplatin in the GR tumor model (p=0.0012). These data may encourage further clinical investigation of oxaliplatin in combination with classical and non-classical thymidylate synthase inhibitors in the treatment of human cancers.

Effects of olomoucine, a selective inhibitor of cyclin-dependent kinases, on cell cycle progression in human cancer cell lines.

We have studied the effects of olomoucine, a selective inhibitor of cdk2, cdc2 and MAP kinase, on the rate of proliferation and the cell cycle progression in human cancer cells in culture. Olomoucine inhibited the growth of the KB 3-1, MDA-MB-231 and Evsa-T cell lines in a concentration-dependent manner, with EC50 values of 45, 75 and 85 microM, respectively. Incubation of exponentially growing KB 3-1 cells in the presence of olomoucine led to an increased proportion of cells in G1 phase after 24 h or more of incubation. Olomoucine failed to rapidly affect the phosphorylation of the Rb tumor-supressor gene product. However, [3H]thymidine incorporation into the cell DNA was rapidly inhibited. We show that this inhibition is due, at least in part, to the diminution of thymidine entry into the cells. Surprisingly, all these cell lines, when synchronized at the G1/S interface and relaxed in the presence of olomoucine, progressed unhindered through the S phase. Under these conditions, the G2 phase transit was markedly retarded but not prevented. Insufficient permeability of the cell membrane to olomoucine may explain the low activity of the drug.

Synergy between the non-classical thymidylate synthase inhibitor AG337 (Thymitaq) and cisplatin in human colon and ovarian cancer cells.

AG337 is the recent non-classical thymidylate synthase inhibitor with promising activity and manageable toxicity in phase I clinical trials. In this study, we investigated the cytotoxic activity of AG337 alone and in combination with cisplatin in cultured human colon (HT29) and ovarian (2008) cancer cell lines and their derived counterparts selected for their resistance to 5-fluorouracil (5-FU) (HT29-5-FU) and cisplatin (2008C13). We observed that AG337 had potent cytotoxic effects in colon (IC50 = 0.17 MicroM) and ovarian cancer cells (IC50 = 0.65 microM). The cytotoxic activity of AG337 was higher than that of 5-FU in the two models. The Activity of AG337 was not significantly affected in 5-FU-resistant HT29-5-FU colon cancer cells characterized by an amplification of the thymidylate synthase gene (IC50 = 0.27 microM, p = 0.15). Combinations of cisplatin and AG337 exert synergistic activity in both ovarian and colon cancer cells. Interestingly, this synergism was maintained in 5-FU- and cisplatin-resistant cells. Therefore, our data encourage further examination of combinations of AG337 with cisplatin in cancer chemotherapy.

Sodium butyrate inhibits the phosphorylation of the retinoblastoma gene product in mouse fibroblasts by a transcription-dependent mechanism.

In the chemically transformed mouse fibroblasts BP-A31, the retinoblastoma protein (pRB) is hypophosphorylated at quiescence and becomes hyperphosphorylated after approximately 6 h of serum stimulation. Phosphorylation of pRb was blocked if sodium butyrate was added together with serum or within 3 h afterwards. Actinomycin D added 3 h after serum stimulation did not prevent pRb phosphorylation, but it reversed the inhibitory effect of butyrate. These observations indicate that sodium butyrate acts by turning on the expression of gene(s) coding for proteins which prevent the accumulation of hyperphosphorylated pRb. Such butyrate-induced inhibitor(s) may interfere with the phosphorylation of pRb by cyclin-dependent kinases. Treatment of quiescent BP-A31 cells with serum in the presence of sodium butyrate has led to an increased cell content of the Waf1/CIP1 mRNA (coding for a cyclin-dependent) kinase inhibitory protein) compared with serum alone, suggesting a possible role of p21Waf1/CIP1. In contrast, the mitogen activated protein kinase (enzyme which has been shown to phosphorylate pRb) was constitutively active in BP-A31 cells, and its activity was not significantly affected by a < or = 3h incubation with sodium butyrate.

Cellular effects of olomoucine, an inhibitor of cyclin-dependent kinases.

Olomoucine (2-(2-hydroxyethylamino)-6-benzylamino-9-methylpurine) has been recently described as a competitive inhibitor (ATP-binding site) of the cell cycle regulating p34cdc2/cyclin B, p33cdk2/cyclin A and p33cdk2/cyclin E kinases, the brain p33cdk5/p35 kinase and the ERK1/MAP-kinase. The unusual specificity of this compound towards cell cycle regulating enzymes suggests that it could inhibit certain steps of the cell cycle. The cellular effects of olomoucine were investigated in a large variety of plant and animal models. This compound inhibits the G1/S transition of unicellular algae (dinoflagellate and diatom). It blocks Fucus zygote cleavage and development of Laminaria gametophytes. Stimulated Petunia mesophyl protoplasts are arrested in G1 by olomoucine. By arresting cleavage it blocks the Laminaria gametophytes. Stimulated Petunia mesophyl protoplasts are arrested in G1 by olomoucine. By arresting cleavage it blocks the development of Calanus copepod larvae. It reversibly inhibits the early cleavages of Caenorhabditis elegans embryos and those of ascidian embryos. Olomoucine inhibits the serotonin-induced prophase/metaphase transition of clam oocytes; furthermore, it triggers the the release of these oocytes from their meiotic metaphase I arrest, and induces nuclei reformation. Olomoucine slows down the prophase/metaphase transition in cleaving sea urchin embryos, but does not affect the duration of the metaphase/anaphase and anaphase/telophase transitions. It also inhibits the prophase/metaphase transition of starfish oocytes triggered by various agonists. Xenopus oocyte maturation, the in vivo and in vitro phosphorylation of elongation factor EF-1 are inhibited by olomoucine. Mouse oocyte maturation is delayed by this compound, whereas parthenogenetic release from metaphase II arrest is facilitated. Growth of a variety of human cell lines (rhabdomyosarcoma cell lines Rh1, Rh18, Rh28 and Rh30; MCF-7, KB-3-1 and their adriamycin-resistant counterparts; National Cancer Institute 60 human tumor cell lines comprising nine tumor types) is inhibited by olomoucine. Cell cycle parameter analysis of the non-small cell lung cancer cell line MR65 shows that olomoucine affects G1 and S phase transits. Olomoucine inhibits DNA synthesis in interleukin-2-stimulated T lymphocytes (CTLL-2 cells) and triggers a G1 arrest similar to interleukin-2 deprivation. Both cdc2 and cdk2 kinases (immunoprecipitated from nocodazole- and hydroxyurea-treated CTLL-2 cells, respectively) are inhibited by olomoucine. Both yeast and Drosophila embryos were insensitive to olomoucine. Taken together the results of this Noah's Ark approach show that olomoucine arrests cells both at the G1/S and the G2/M boundaries, consistent with the hypothesis of a prevalent effect on the cdk2 and cdc2 kinases, respectively.

Antiproliferative effects of sodium butyrate in adriamycin-sensitive and -resistant human cancer cell lines.

The proliferation of the MCF7 and MCF7-A (adriamycin-resistant) and KB-3-1 and KB-A (adriamycin-resistant) cell lines was arrested by sodium butyrate (NaBut) at 1 mM or higher concentrations. In the MCF7 and MCF7-A cell lines, an accumulation in the G1 phase was observed, whereas the KB-3-1 and KB-A cell lines accumulated in both G1 and G2/M phases. The level of the mRNA coded by the 'early G1' gene c-myc was high in all these cell lines, and was only transiently decreased by NaBut treatment. The 'late' mRNA coding for the proliferating cell nuclear antigen (PCNA) was also strongly expressed in all the cell lines studied; incubation with NaBut caused a decrease of the PCNA mRNA in the MCF7 and MCF7-A cells but not in the KB-3-1 and KB-A cells. The anti-oncoprotein p105RB was undetectable in the MCF7 and MCF7-A cells, while the KB-3-1 as well as KB-A cells contained a high level of this protein. Neither the content nor the apparent state of phosphorylation of the RB protein were affected by incubation (up to 48 h) with NaBut.

Mitogenic signaling by prostaglandins in chemically transformed mouse fibroblasts: comparison with phorbol esters and insulin.

In the quiescent mouse BP-A31 fibroblasts, prostaglandin F2 alpha (PGF2 alpha) induces the expression of cell cycle-related genes c-fos, c-jun, and c-myc, and after a delay of approximately 12 h the entry into the phase of DNA replication. A weaker mitogenic effect was produced by certain other PGs (F1 alpha > D2), whereas the effects of PGs E and I were marginal or absent. The mitogenic effects of PGF2 alpha as well as of 12-O-tetradecanoyl phorbol 13-acetate (TPA; activator of protein kinase C) but not those of insulin (acting via the insulin-like growth factor 1 receptor) were abolished by a low concentration (7.5 nM) of staurosporine (inhibitor of protein kinase C). Moreover, long-time (24 h) preincubation with phorbol dibutyrate reduced the mitogenic effects of a subsequent exposure either TPA or PGF2 alpha. These observations favor the involvement of protein kinase C in the PGF2 alpha-dependent intracellular signal transduction. However, simultaneous stimulation of the quiescent cells with saturating concentrations of PGF2 alpha and TPA had a greater mitogenic effect than either drug alone, both in cells with and without down-regulation of protein kinase C, indicating that the protein kinase C-dependent signaling does not entirely account for the mitogenic activity of PGF2 alpha.

Cell cycle dependent regulation of cdc2 mRNA in mouse fibroblasts: requirement of protein synthesis and of continued mitogenic stimulation.

In the chemically transformed mouse fibroblasts (BP-A31) placed in a serum-free medium, the cdc2 mRNA content decreases in parallel with the cessation of [3H]thymidine incorporation. Extinction of the cdc2 gene expression is also observed in BP-A31 cells overexpressing the human c-myc oncogene. At quiescence, the cdc2 gene expression can be reinduced with serum or with other mitogens such as insulin or 12-O-tetradecanoyl phorbol 13-acetate (TPA). The kinetics of induction is characterized by a lag period which differs according to the mitogen used and reflects the length of the G1 phase (4-6 h with insulin or serum, 9-12 h with TPA). The cdc2 mRNA accumulation is prevented when protein synthesis is blocked with cycloheximide, also if the drug is added at a time when the synthesis of cdc2 mRNA is already under way. Similarly, removal of the mitogen leads to a cessation of the cdc2 mRNA accumulation. These results suggest that the increased expression of the cdc2 gene is mediated by (a) short-lived, growth factor-regulated protein(s).

Antimitogenic effects of dexamethasone in chemically transformed mouse fibroblasts.

Dexamethasone (a synthetic glucocorticoid) inhibited the entry into the S-phase of quiescent chemically transformed mouse fibroblasts (BP-A31) stimulated with 12-O-tetradecanoyl 13-acetate (TPA; a protein kinase-C activator) or with basic fibroblast growth factor. The basal rate of DNA synthesis was also strongly reduced by dexamethasone. In contrast, the mitogenic activity of insulin (acting via the insulin-like growth factor-I receptor) was little or not at all affected by dexamethasone. The antimitogenic activity of dexamethasone was enhanced when the steroid was included in the culture medium 24 h before the addition of mitogens. The effects of dexamethasone were glucocorticoid specific, partially reversed by the antiglucocorticoid RU 486, and prevented by cycloheximide (suggesting the involvement of glucocorticoid-induced protein synthesis in the antimitogenic activity of dexamethasone). Under the conditions of exponential growth in serum-free medium as well as in the presence of TPA, dexamethasone arrested the proliferation of sparsely seeded cells after a delay of 24-48 h. The BP-A31 cells are known to be constitutively competent and express at quiescence certain genes related to the G0/G1 transition in the original nontransformed A31 cell line. Of the transcripts corresponding to these genes, dexamethasone caused a rapid elimination of the JE mRNA, coding for a protein of the family of cytokines. The cell content of c-jun mRNA was also strongly reduced in the cells incubated at quiescence with dexamethasone (in the absence of mitogen). The presence of TPA along with dexamethasone prevented the elimination of c-jun, but not of JE mRNA. Short (30-min; together with the inducers) or long (24-h) treatment of the cells with dexamethasone did not prevent the induction of the c-fos gene expression by either TPA or basic fibroblast growth factor, indicating that dexamethasone does not interfere with mitogenic signal transduction. We conclude that in TPA-stimulated cells, the antiproliferative effect of dexamethasone is not due to interference with the expression of the c-jun gene, but may be related to the decreased level of the JE cytokine mRNA as well as to the synthesis of growth inhibitory protein(s).