Jeannine S. Strobl

Potassium Channels, Proliferation and G1 Progression

Potassium channels are the most ubiquitous and diverse family of plasma membrane ion channels, and this is reflected in a large variety of essential roles they perform in different cells. Voltage-gated K channels modulate the excitability of excitable cells, and K channels gated by intracellular ligands, such as calcium or ATP, provide a functional link between the physiological properties of the plasma membrane and the activity of intracellular metabolic pathways. There is now substantial evidence that drugs which block K channels also inhibit the proliferation of many types of cells, but the cellular mechanism(s) by which the level of K channel activity might be related to proliferation remains unclear. A particularly intriguing possibility is that the opening, or activation, of K channels might be required for the passage of cells through a specific stage in their cell cycle; this would provide a fundamental link between physiological and biochemical signaling pathways which regulate progression through the cell cycle (Fig. 1). The role of K channels in mitogenesis and proliferation has been previously reviewed [20,24,60]. The focus of the present review is the hypothesis that the activation of K channels is required for cells to progress through the G1 phase of the cell cycle. We will examine first the evidence supporting this hypothesis, and then we will discuss the processes or events within G1 phase that are most likely to require the activation of K channels. Identification of these critical events is important because their dependence on the activation of ion channels in the plasma membrane would represent a novel type of regulatory checkpoint, compared to other checkpoints previously identified within the G1 phase of the cell cycle [66].

Rapid Induction of Histone Hyperacetylation and Cellular Differentiation in Human Breast Tumor Cell Lines following Degradation of Histone Deacetylase-1

Quinidine inhibits proliferation and promotes cellular differentiation in human breast tumor epithelial cells. Previously we showed quinidine arrested MCF-7 cells in G1 phase of the cell cycle and led to a G1 to G0 transition followed by apoptotic cell death. The present experiments demonstrated that MCF-7, MCF-7ras, T47D, MDA-MB-231, and MDA-MB-435 cells transiently differentiate before undergoing apoptosis in response to quinidine. The cells accumulated lipid droplets, and the cytokeratin 18 cytoskeleton was reorganized. Hyperacetylated histone H4 appeared within 2 h of the addition of quinidine to the medium, and levels were maximal by 24 h. Quinidine-treated MCF-7 cells showed elevated p21 WAF1 , hypophosphorylation and suppression of retinoblastoma protein, and down-regulation of cyclin D1, similar to the cell cycle response observed with cells induced to differentiate by histone deacetylase inhibitors, trichostatin A, and trapoxin. Quinidine did not show evidence for direct inhibition of histone deacetylase enzymatic activity in vitro. HDAC1 was undetectable in MCF-7 cells 30 min after addition of quinidine to the growth medium. The proteasome inhibitors MG-132 and lactacystin completely protected HDAC1 from the action of quinidine. We conclude that quinidine is a breast tumor cell differentiating agent that causes the loss of HDAC1 via a proteasomal sensitive mechanism.

Mitogenic signal transduction in human breast cancer cells

1. Signal transduction pathways activated during growth of human breast cancer cells in tissue culture are reviewed. 2. Steroid hormones and growth factors stimulate similar mitogenic pathways and frequently modulate each others activity. 3. A response common to estrogen, progestins and most polypeptide mitogens is induction of the nuclear transcription factors myc, fos and jun in early G1 phase of the cell cycle. 4. Some growth factors also stimulate cyclin D1, a regulatory protein responsible for the activation of cell cycle-dependent kinases in G1. 5. In addition, insulin, IGF-I and EGF activate tyrosine kinase receptors. 6. Several tyrosine phosphorylated proteins occur in human breast cancer cells, and include the EGF and estrogen receptors. 7. Cyclic AMP plays a critical role in breast cancer cell proliferation through the activation of protein kinase A, and it also modulates the activity of estrogen and progesterone receptors. 8. EGF is the only breast cell mitogen known to raise intracellular free calcium levels. 9. Calcium may play a dual role in breast cancer cell proliferation, activating both calmodulin-dependent processes and regulating cell membrane potential through the activation of potassium channels. 10. Potassium channel activity and cell proliferation are linked in breast cancer cells, the cell membrane potential shifting between a depolarized state in G1/G0 cells and a hyperpolarized state during S phase. 11. Activation of an ATP-sensitive potassium channel is required for breast cancer cells to undergo the G1/G0-S transition.

A sequence in the 5′ flanking region confers progestin responsiveness on the human c-myc gene

Previous reports have shown that progestins stimulate the proliferation of the human breast cancer cell line T47D in culture. Under different conditions other reports have shown progestin stimulation, inhibition or no effect on growth. It has also been shown that c-myc expression is stimulated at early times by progestins. We are currently testing the hypothesis that the mechanism of growth enhancement by progestins involves the stimulation of expression of c-myc. This hypothesis predicts a progesterone regulatory region in or near the c-myc gene. We have identified a region, from -2327 to -1833, which serves this function. This region includes a 15 bp sequence with homology to the PRE (progesterone response element) consensus sequence. Human progesterone receptor (PR) binds to this sequence in a specific, ligand-enhanced manner in electrophoretic mobility shift assays (EMSA). A 3507 bp HindIII-XbaI fragment of the 5 flanking region of the c-myc gene, -2327 to +1180, containing the progestin regulatory region and the c-myc promoter, confers progestin responsiveness to the CAT (chloramphenicol acetyl transferase) reporter gene in progesterone receptor (PR)-rich T47D human breast cancer cells, but not in PR-negative MDA-MB-231 cells. Removal of the progestin regulatory region abrogates progestin responsiveness. These data demonstrate that the sequence from -2327 to -1833 of the human c-myc gene includes a positive progestin regulatory region.

Extinction of growth hormone expression in somatic cell hybrids involves repression of the specific trans-activator GHF-1

Growth hormone (GH) expression in pituitary-derived cells has been attributed to the presence of a positive trans-activator, GHF-1, which binds to two sites on the GH promoter. Somatic cell hybridization of non-GH-expressing L cells with pituitary-derived GH3 cells usually results in extinction of GH production. While previous studies showed that extinction occurs at the level of GH transcription, the exact mechanism remained elusive. We therefore characterized two parental cell lines and three hybrids, two of which extinguish GH expression and one in which GH is reexpressed after loss of mouse chromosomal material. Using in vivo transfections, in vitro transcription, DNAase I footprints, and immunoblotting experiments, no evidence for a direct repressor of GH transcription was found. Rather, extinction of GH expression in fibroblast x pituitary hybrids was accompanied by loss of GHF-1 protein and mRNA expression, suggesting that extinction occurs by repression of this trans-activator.

Actions of a Histone Deacetylase Inhibitor NSC3852 (5-Nitroso-8-quinolinol) Link Reactive Oxygen Species to Cell Differentiation and Apoptosis in MCF-7 Human Mammary Tumor Cells

NSC3852 (5-nitroso-8-quinolinol) has cell differentiation and antiproliferative activity in human breast cancer cells in tissue culture and antitumor activity in mice bearing P388 and L1210 leukemic cells. We investigated the mechanism of NSC3852 action in MCF-7 human breast cancer cells using electron spin resonance (ESR). Reactive oxygen species (ROS) were detected in MCF-7 cell suspensions incubated with NSC3852 using the spin trap 5,5-dimethyl-1-pyrroline-N-oxide (DMPO). Formation of the DMPO-OH adduct was quenched by the addition of superoxide dismutase but not by catalase, and we concluded that superoxide was generated in the NSC3852-treated cells. The flavoprotein inhibitor diphenylene iodonium suppressed ROS production, providing evidence for the involvement of a flavin-dependent enzyme system in the ROS response to NSC3852. A biologically significant oxidative response to NSC3852 occurred in MCF-7 cells. An early marker of oxidative stress was a decrease in the [glutathione]/[glutathione disulfide] ratio 1 h after NSC3852 addition. Oxidative DNA damage, marked by the presence of 8-oxoguanine, and DNA-strand breakage occurred in cells exposed to NSC3852 for 24 h. Apoptosis peaked 48 h after exposure to NSC3852. Pretreatment with the glutathione precursor N-acetyl-l-cysteine (NAC) prevented DNA-strand breakage and apoptosis. Pretreatment with NAC also reversed NSC3852 decreases in E2F1, Myc, and phosphorylated retinoblastoma protein, indicative of redox-sensitive pathway(s) in MCF-7 cells during G1 phase of the cell cycle. We conclude that ROS formation is involved in the apoptotic and cell differentiation responses to NSC3852 in MCF-7 cells.

Control of Mammary Tumor Cell Growth in Vitro by Novel Cell Differentiation and Apoptosis Agents

The use of breast tumor differentiating agents to complement existing therapies has the potential to improve breast cancer treatment. Previously we showed quinidine caused MCF-7 cells to synchronously arrest in G1 phase of the cell cycle, transition into G0 and undergo progressive differentiation. After 72–96 h cells became visibly apoptotic. Using several analogs of quinidine we determined that MCF-7 cell cycle exit and differentiation are typical of quinoline antimalarial drugs bearing a tertiary amine side chain (chloroquine, quinine, quinidine). Differentiated cells accumulated lipid droplets and mammary fat globule membrane protein. Apoptosis was assayed by a nucleosome release ELISA. Quinidine and chloroquine triggered apoptosis, but not quinine, a quinidine stereoisomer that displayed weak DNA binding. The apoptotic response to quinidine and chloroquine was p53-dependent. A 4–15-fold induction of p21(WAF1) protein was observed in cells treated with quinidine or chloroquine prior to apoptosis, but p21(WAF1) was not increased in cells that differentiated in response to quinine. Chloroquine was most active in stimulating MCF-7 apoptosis, and quinine was most active in promoting MCF-7 cell differentiation. We conclude, distinct mechanisms are responsible for breast tumor cell differentiation and activation of apoptosis by quinoline antimalarials. Alkylamino-substituted quinoline ring compounds represented by quinidine, quinine, and chloroquine will be useful model compounds in the search for more active breast tumor differentiating agents.

The cell death response to γ-radiation in MCF-7 cells is enhanced by a neuroleptic drug, pimozide

Neuroleptic drugs that bind sigma sites were tested for their ability to inhibit growth and radiosensitize MCF-7 human breast cancer cells. Inhibition of growth by ∼ 50% occurred in cells exposed to pimozide (0.6 μM), haloperidol (10 μM), and the sigma ligand DTG (1,3-di(2-tolyl)guanidine, 20 μM), but no growth inhibition occurred in cells exposed to clozapine, a neuroleptic drug lacking sigma binding activity, or dextromethorphan, a selective sigma 1 binding ligand. Pimozide (2.5 μM), but not haloperidol (3.6 μM), enhanced the sensitivity of MCF-7 cells to γ radiation in clonogenic survival assays. Pimozide significantly decreased MCF-7 clonogenic survival following a 5 or 8 Gy dose of γ radiation, and the dose of radiation required for 1% survival (survival enhancement ratio, SER) was decreased by a factor of 2. Exposure of normal WI-38 human embryonic lung cells to pimozide did not increase their sensitivity to γ radiation. Pimozide (2.5 μM) activated early apoptotic changes in MCF-7 cells that were detected by the uptake of Hoechst 33342 dye, and 10 μM pimozide activated a complete apoptotic pathway resulting in the death of > 90% of the cells within 24 hours. MCF-7 cells exposed to γ radiation alone (8 Gy) showed giant cell formation, mitotic arrest, and a limited degree of apoptosis and necrosis. Within 50 hours of treatment with a combination of radiation and pimozide, cell numbers were sharply reduced compared with cultures exposed to either radiation or pimozide alone. We conclude that pimozide augmented the sensitivity of MCF-7 cells to radiation-induced cell killing through a mechanism not shared by haloperidol, but suggest that concentration of pimozide in MCF-7 cells as a result of an enrichment of sigma 2 sites might target the radiosensitization.

A survey of human breast cancer sensitivity to growth inhibition by calmodulin antagonists in tissue culture

We compared the ability of N-(4-aminobutyl)-5-chloro-2-naphthalenesulfonamide (W-13), a calmodulin antagonist, to inhibit the growth of seven human breast cancer cell lines in tissue culture, to determine whether drug sensitivity was related to estrogen receptor (ER) status, tamoxifen resistance (tamr), or levels of calmodulin activity. We examined three ER+ (estrogen receptor-positive) cell lines (MCF-7, ZR-75-1B, and T47D), two ER+/tamr lines (LY2 and RR), and two ER- (estrogen receptor-negative) cell lines (MDA-MB-231 and MDA-MB-435). There was no difference in the inhibition of cell growth by W-13 in MCF-7 cells and the two tamr MCF-7 cell derivatives, LY2 and RR. In addition, the sensitivity to W-13 did not appear to be related to ER status. Although the mean Ki of the five ER+ cell lines (31 microM) was somewhat higher than the mean Ki of the two ER- cell lines (23 microM), the two cell lines most sensitive to W-13 were the ER+ T47D cells (Ki 15 microM) and the ER- MDA-MB-435 cells (Ki 10 microM). Calmodulin activity was measured in three representative cell lines, MCF-7, LY2, and MDA-MB-435. Calmodulin levels were higher in the most sensitive cell line (MDA-MB-435, 2.7 ng calmodulin/micrograms protein) than in the two less sensitive cell lines, MCF-7 and LY2 (1.3 and 1.6 ng calmodulin/micrograms protein, respectively). However, the MCF-7, LY2, and MDA-MB-435 cells were equally sensitive to another specific calmodulin antagonist, calmidazolium. We conclude that neither ER status, tamoxifen resistance, nor levels of calmodulin activity predict the sensitivity of human breast cancer cell lines to growth inhibition in tissue culture by calmodulin antagonists.

Dexamethasone control of growth hormone mRNA levels in GH3 pituitary cells is cycloheximide-sensitive and primarily posttranscriptional

To clarify the mechanism of growth hormone (GH) gene activation by glucocorticoids in GH3 pituitary cells, GH mRNA accumulation in nuclear and cytoplasmic compartments was measured in the presence and absence of cycloheximide. In dexamethasone-treated cells, levels of GH mRNA were increased in the nucleus by 6 h and in the cytoplasm by 12 h. Dexamethasone treatment caused a 5- to 24-fold rise in total GH mRNA levels by 48-72 h. The differential elevation of nuclear levels of GH mRNA relative to the amount of cytoplasmic GH mRNA persisted for 48 h. A transient accumulation of GH mRNA in the nucleus was followed by a brief rise in cytoplasmic GH mRNA levels in GH3 cells treated simultaneously with dexamethasone and cycloheximide. In GH3 cells pretreated for 2 h with cycloheximide, the rise in nuclear and cytoplasmic GH mRNA levels mediated by dexamethasone was blocked completely. Levels of glucocorticoid receptor were unaffected by cycloheximide. These data suggest that the stimulation of GH mRNA levels by glucocorticoids is initiated within the nucleus and that cycloheximide-sensitive events are essential for this stimulation to occur. To assess the importance of GH gene transcriptional activation by glucocorticoids, nuclear transcription run-on reactions and assays of GH promoter activity in an aminoglycoside 3-phosphotransferase (Neo) fusion gene within stably transformed GH3 cells were performed. Evidence for a weak, transient transcriptional activation of the GH gene by dexamethasone in nuclear run-on assays was obtained. Consistent with this idea, a 30-72 h exposure to dexamethasone raised levels of Neo mRNA in GH-Neo GH3 cell transformants by less than or equal to 2-fold. We conclude that glucocorticoid stimulation of GH mRNA in GH3 cells requires ongoing protein synthesis and can occur largely independently of GH gene transcriptional activation.