Raf/MEK/ERK signaling inhibition enhances the ability of dequalinium to induce apoptosis in the human leukemic cell line K562.

Delocalized lipophilic cations, such as dequalinium (DQA), selectively accumulate in mitochondria and display anticancer activity in cells from different malignancies. Previous studies in K562 human leukemic cells indicate that DQA causes cell damage as a consequence of an early disturbance in the mitochondrial function, inducing oxidative stress. These cells turned out to be resistant to apoptosis and died by necrosis when treated with high DQA concentrations (20 µmol/L) for long time periods (48 h). Resistance of K562 cells to DQA-induced apoptosis could be eliminated by inhibition of the kinase activity of the Bcr-Abl protein with imatinib. In this paper, we have studied the effect of DQA on the Raf/MEK/ERK1/2 and PI3K/Akt signal transduction pathways in K562 cells. Our data suggest a DQA downregulatory activity on both ERK1/2 and PI3K protein kinase activity supporting an interaction between both proteins. Moreover, inhibition of ERK1/2 with U0126 enhanced the ability of DQA to potentiate imatinib-induced apoptosis, suggesting a role of the Raf/MEK/ERK pathway and the Bcr-Abl tyrosine kinase in the K562 cell survival. This study contributes to a better understanding of the action mechanism of DQA on K562 cells and encourages the study of DQA in combination with other agents for improving the efficacy of targeted therapies and overcoming resistance to chemotherapeutic agents.

Dequalinium induces apoptosis in peripheral blood mononuclear cells isolated from human chronic lymphocytic leukemia.

B-cell chronic lymphocytic leukemia (B-CLL) is an abnormal neoplasic proliferation of B cells, which accumulate mainly in the bone marrow and blood preventing both B cells development in the lymph nodes and the ability to fight against infection. The antitumor agents used in chemotherapy are aimed at inducing malignant cell death, thus limiting the growth and spreading of these cells. However, the lack of specificity for tumor cells exhibited by these agents causes undesirable side effects that have led to the investigation of new therapeutic strategies designed to specifically target malignant cells and thus trigger selective cell destruction. Dequalinium (DQA) is an antitumoral agent that selectively accumulates in the mitochondria and has been shown to display anticancer activity in cells from different malignancies. In the present study, the DQA-induced cytotoxicity in B-CLL cells was analyzed by measuring cell viability and cell death, either by necrosis or apoptosis. Our results support the importance of DQA as a selective and potential antileukemic drug with a higher cytotoxic effect on peripheral blood mononuclear cells from B-CLL patients than in those from healthy donors and encourage the performance of further studies in combination with other agents.

Induction of petite mutants in yeast Saccharomyces cerevisiae by the anticancer drug dequalinium.

Dequalinium (DEQ), a drug with both antimicrobial and anticancer activity, induced the formation of petite (respiration-deficient) mutants in the yeast Saccharomyces cerevisiae. DEQ was found to be approximately 50-fold more potent than ethidium bromide (EB) at inducing petites. Analysis of the DEQ-induced petite mutants indicated a complete loss of mitochondrial DNA (<1 copy/cell). Prior to the loss of mtDNA, DEQ caused cleavage of the mtDNA into a population of fragments 30-40kbp in size suggesting that this drug causes petites by inducing a breakdown of mtDNA. The selective effect of DEQ on yeast mtDNA may underlie the antifungal activity of this chemotherapeutic agent.

Comparative in vitro evaluation of dequalinium B, a new boron carrier for neutron capture therapy (NCT).

A boronated derivative of dequalinium, a delocalized lipophilic cation (DLC), was synthesized as a potential boron carrier for the selective targeting of mitochondria in malignant versus benign cells for boron neutron capture therapy (BNCT), a binary modality for the treatment of cancer. This agent, designated DEQ-B, was taken up and retained in vitro in the KB, F98, and C6 tumor cell lines but not in the normal epithelial cell line CV1. DEQ-B was also less toxic in the latter cell line at lower exposure concentrations The uptake, retention, and toxicity profiles of DEQ-B are comparable to those of the non-boronated DLCs, dequalinium, MKT 077, RH 123, and tetraphenylphosphonium chloride. Our results suggest that the synthesis and further evaluation of boronated DLCs as potential delivery agents for BNCT is warranted.

Site of action of suramin and reactive blue 2 in preventing neuronal death induced by dequalinium.

Dequalinium (DQ, an anticancer drug) is a potent neurotoxicant in the cultured developing cerebellar granule neurons (CGNs) with an IC(50) of 1.31. M after 24 hr incubation. By utilizing fluorometric technique, we found that DQ initially induced apoptosis and then necrosis associated with a marked decrease in ATP contents. The purinergic P(2) receptor antagonists (suramin, and reactive blue 2) prevented DQ-cytotoxicity, although glutamate ionotropic receptor antagonists (MK 801 and NBQX) could not. Furthermore, we quantitatively determined a reduction of mitochondrial membrane potential and an increase of free radical production induced by DQ. Suramin abolished these detrimental events of DQ. This suggests that neuronal death induced by DQ is mediated, at least in part, through a signaling pathway of free radical production-mitochondrial dysfunction. Further evidence supporting this contention is that CGN progressively became more sensitive to both DQ-induced cytotoxicity and reduced mitochondrial membrane potential. This implies that neuronal mitochondria are apparently one of the target sites for DQ and suramin and directly or indirectly induce neurotoxicity and neuroprotection respectively. The alteration in mitochondrial membrane potential during neuronal maturation may be one of the determinants accounting for the increased susceptibility to neurotoxicants such as DQ.

Toxicity of the mitochondrial poison dequalinium chloride in a murine model system.

Dequalinium chloride (DECA), a cationic, lipophilic mitochondrial poison, selectively targets the mitochondrial membrane of certain epithelial carcinoma cells, in which it inhibits cellular energy production. It has demonstrated potency as a cytotoxic agent specific for carcinomas and may provide a novel approach for cancer therapy, either as a single agent or as an adjunct to conventional chemotherapy. The purpose of this study was to determine the toxicity of DECA in the murine model. One hundred female BALB/c mice were divided into three schedule groups. Group one received a single intraperitoneal (ip) dose of DECA at 10, 15, 20, or 25 mg/kg of body weight. Group two received DECA at 6, 7, 8, 9, or 10 mg/kg ip every other day (QOD), and group three received DECA at 10, 11, 12, 13, or 14 mg/kg ip every 7 days. Over a 30- to 60-day period, acute and subchronic toxicities were evaluated on the basis of the following clinical parameters: respiratory distress, weight loss, and mortality. After a single ip administration, we found a maximum tolerated dose of 15 mg/kg and a lethal dose (LD50) of 18.3 mg/kg. Single ip doses of 20 and 25 mg/kg produced > 50% mortality. Histologic examination of the tissues revealed significant damage to the liver and kidneys, with pulmonary congestion occurring secondary to renal-hepatic failure. A cumulative assessment revealed that 60% of the animals tolerated 15 doses of 6 and 7 mg/kg QOD and that 100% tolerated 5 doses of 11 and 12 mg/kg (every 7 days). Higher DECA doses under either regimen induced severe toxic effects and mortality.(ABSTRACT TRUNCATED AT 250 WORDS)

Enhanced in vitro uptake and retention of 3H-tetraphenylphosphonium by nervous system tumor cells.

Photodynamic therapy is a promising treatment for human brain tumors because of the selective retention of certain compounds by tumor cells. Certain lipophilic cationic compounds, such as tetraphenylphosphonium (TPP), are selectively taken up by a variety of carcinomas. Although preferential retention of TPP has been demonstrated for the breast carcinoma cell line MCF-7, this compound had not been tested previously on cells derived from nervous system tumors. In the present study, tritiated-TPP (3H-TPP) uptake and retention for eight different cell cultures of three histologically different types of nervous system tumors was measured and the data were compared to a positive control (MCF-7) and negative controls (normal African Green monkey kidney epithelium (CV-1) and the normal human fibroblast (WI-38) cell lines). Uptake and retention characteristics could be grouped by specific pathological tumor types, but individual tumor variability was notable. Malignant astrocytoma (grade III/III glioblastoma) and malignant neurofibrosarcoma cells showed preferential uptake and retention of 3H-TPP relative to meningioma cells and normal controls. A clonogenic assay utilizing the cytotoxic lipophilic cationic compound dequalinium showed strong retainers of 3H-TPP to be more susceptible to the effects of dequalinium than weak retainers. These data demonstrate that certain human and experimental animal nervous system tumor cell lines retain lipophilic compounds possessing a delocalized positive charge. Lipophilic cationic compounds may be useful in the intraoperative delineation of tumor margins and in the photodynamic therapy of certain nervous system tumors.