Dose-Dependent ATP Depletion and Cancer Cell Death following Calcium Electroporation,Relative Effect of Calcium Concentration and Electric Field Strength

Background

Electroporation, a method for increasing the permeability of membranes to ions and small molecules, is used in the clinic with chemotherapeutic drugs for cancer treatment (electrochemotherapy). Electroporation with calcium causes ATP (adenosine triphosphate) depletion and cancer cell death and could be a novel cancer treatment. This study aims at understanding the relationship between applied electric field, calcium concentration, ATP depletion and efficacy.

Methods

In three human cell lines — H69 (small-cell lung cancer), SW780 (bladder cancer), and U937 (leukaemia), viability was determined after treatment with 1, 3, or 5 mM calcium and eight 99 μs pulses with 0.8, 1.0, 1.2, 1.4 or 1.6 kV/cm. Fitting analysis was applied to quantify the cell-killing efficacy in presence of calcium. Post-treatment intracellular ATP was measured in H69 and SW780 cells. Post-treatment intracellular ATP was observed with fluorescence confocal microscopy of quinacrine-labelled U937 cells.

Results

Both H69 and SW780 cells showed dose-dependent (calcium concentration and electric field) decrease in intracellular ATP (p<0.05) and reduced viability. The 50% effective cell kill was found at 3.71 kV/cm (H69) and 3.28 kV/cm (SW780), reduced to 1.40 and 1.15 kV/cm (respectively) with 1 mM calcium (lower EC50 for higher calcium concentrations). Quinacrine fluorescence intensity of calcium-electroporated U937 cells was one third lower than in controls (p<0.0001).

Conclusions

Calcium electroporation dose-dependently reduced cell survival and intracellular ATP. Increasing extracellular calcium allows the use of a lower electric field.

General Significance

This study supports the use of calcium electroporation for treatment of cancer and possibly lowering the applied electric field in future trials.     

Cell Swelling, Blebbing, and Death Are Dependent on ATP Depletion and Independent of Calcium During Chemical Hypoxia in a Glial Cell Line (ROC-1)

The morphological and biochemical changes that occur during chemical hypoxic injury in a neural cell line were studied in the presence and absence of calcium. Oligodendroglial-glioma hybrid cells (ROC-1) were subjected to inhibitors of glycolytic and oxidative ATP synthesis (chemical hypoxia). Complete respiratory inhibition depleted [ATP] to less than 5% of control by 4 min. Blebs appeared on the cell surfaces and cells began to swell within a few minutes of ATP depletion. A 200% increase in cell volume and bleb coalescence preceded irreversible cell injury (lactate dehydrogenase release) which began at approximately 20 min with 50% cell death by 40 min. In energized cells an equivalent degree of osmotic swelling induced by ouabain inhibition of the Na+, K(+)-ATPase pump did not produce blebbing or cell death. Partial inhibition of respiration decreased [ATP] to approximately 10% of control by 40 min. Blebbing and swelling began at 40 min and bleb coalescence preceded plasma membrane disruption which began at approximately 55 min. ATP depletion, blebbing, swelling, and death followed similar time courses in the presence or absence of extracellular calcium ([Ca2+]e). Intracellular calcium ([Ca2+]i) was measured using fura-2. In calcium-containing medium metabolic inhibition caused a transient increase in resting [Ca2+]i (100 +/- 17 nM) followed by a low steady-state level preceding plasma membrane disruption. Following deenergization in calcium-free medium, [Ca2+]i remained below 60 nM throughout injury and death. These data suggest that decreased ATP initiates a sequence of events including bleb formation and cell swelling that lead to irreversible cell injury in the absence of large increases in [Ca2+]i.     

Chemical Hypoxia-Induced Cell Death in Human Glioma Cells: Role of Reactive Oxygen Species,ATP Depletion,Mitochondrial Damage and Ca2+

This study was undertaken to evaluate whether chemical hypoxia-induced cell injury is a result of reactive oxygen species (ROS) generation, ATP depletion, mitochondrial permeability transition, and an increase in intracellular Ca²⁺, in A172 cells, a human glioma cell line. Chemical hypoxia was induced by incubating cells with antimycin A, an inhibitor of mitochondrial electron transport, in a glucose-free medium. Exposure of cells to chemical hypoxia resulted in cell death, ROS generation, ATP depletion, and mitochondrial permeability transition. The H₂O₂ scavenger pyruvate prevented cell death, ROS generation, and mitochondrial permeability transition induced by chemical hypoxia. In contrast, changes mediated by chemical hypoxia were not affected by hydroxyl radical scavengers. Antioxidants did not affect cell death and ATP depletion induced by chemical hypoxia, although they prevented ROS production and mitochondrial permeability transition induced by chemical hypoxia. Chemical hypoxia did not increase lipid peroxidation even when antimycin A was increased to 50 M, whereas the oxidant t-butylhydroperoxide caused a significant increase in lipid peroxidation, at a concentration that is less effective than chemical hypoxia in inducing cell death. Fructose protected against cell death and mitochondrial permeability transition induced by chemical hypoxia. However, ROS generation and ATP depletion were not prevented by fructose. Chemical hypoxia caused the early increase in intracellular Ca²⁺. The cell death and ROS generation induced by chemical hypoxia were altered by modulation of intracellular Ca²⁺ concentration with ruthenium red, TMB-8, and BAPTA/AM. However, mitochondrial permeability transition was not affected by these compounds. These results indicate that chemical hypoxia causes cell death, which may be, in part, mediated by H₂O₂ generation via a lipid peroxidation-independent mechanism and elevated intracellular Ca²⁺. In addition, these data suggest that chemical hypoxia-induced cell death is not associated directly with ATP depletion and mitochondrial permeability transition.     

Glutathione Depletion and Carbon Ion Radiation Potentiate Clustered DNA Lesions,Cell Death and Prevent Chromosomal Changes in Cancer Cells Progeny

Poor local control and tumor escape are of major concern in head-and-neck cancers treated by conventional radiotherapy or hadrontherapy. Reduced glutathione (GSH) is suspected of playing an important role in mechanisms leading to radioresistance, and its depletion should enable oxidative stress insult, thereby modifying the nature of DNA lesions and the subsequent chromosomal changes that potentially lead to tumor escape.This study aimed to highlight the impact of a GSH-depletion strategy (dimethylfumarate, and l-buthionine sulfoximine association) combined with carbon ion or X-ray irradiation on types of DNA lesions (sparse or clustered) and the subsequent transmission of chromosomal changes to the progeny in a radioresistant cell line (SQ20B) expressing a high endogenous GSH content. Results are compared with those of a radiosensitive cell line (SCC61) displaying a low endogenous GSH level.DNA damage measurements (γH2AX/comet assay) demonstrated that a transient GSH depletion in resistant SQ20B cells potentiated the effects of irradiation by initially increasing sparse DNA breaks and oxidative lesions after X-ray irradiation, while carbon ion irradiation enhanced the complexity of clustered oxidative damage. Moreover, residual DNA double-strand breaks were measured whatever the radiation qualities. The nature of the initial DNA lesions and amount of residual DNA damage were similar to those observed in sensitive SCC61 cells after both types of irradiation. Misrepaired or unrepaired lesions may lead to chromosomal changes, estimated in cell progeny by the cytome assay. Both types of irradiation induced aberrations in nondepleted resistant SQ20B and sensitive SCC61 cells. The GSH-depletion strategy prevented the transmission of aberrations (complex rearrangements and chromosome break or loss) in radioresistant SQ20B only when associated with carbon ion irradiation. A GSH-depleting strategy combined with hadrontherapy may thus have considerable advantage in the care of patients, by minimizing genomic instability and improving the local control.     

Effect of Direct-Current Electric Field on Enzymatic Activity and the Concentration of Laccase

This work investigates the effect of direct-current electric field on the extracellular enzymatic activity, concentration and other experimental parameters of laccase from Trametes versicolor. The results showed that laccase could significantly contribute to the change of pH at the end of graphite electrode. In addition, it increased the electrical conductivity of the water. In the experiment, the optimum pH and catalytic pH range for laccase activity were 3.0 and pH 2.5–4.0. The application of 6 V direct current showed significant effects on the laccase enzyme activity. The activity of laccase was enhanced in the anodic region, but at the same time was strongly inhibited at the cathode. The electric charge characteristics of laccase were changed when exposed to electric field, and some laccases molecules moved to the anode, which produced a slight migration phenomenon. This study is the basis of combination of laccase and electrical technology, at the same time, providing a new direction of enhancing laccase activity. Compared to immobilization, using electric field is simple, no chemical additives, and great potential.     

DC Electric Fields Direct Breast Cancer Cell Migration, Induce EGFR Polarization, and Increase the Intracellular Level of Calcium Ions

Migration of cancer cells leads to invasion of primary tumors to distant organs (i.e., metastasis). Growing number of studies have demonstrated the migration of various cancer cell types directed by applied direct current electric fields (dcEF), i.e., electrotaxis, and suggested its potential implications in metastasis. MDA-MB-231 cell, a human metastatic breast cancer cell line, has been shown to migrate toward the anode of dcEF. Further characterizations of MDA-MB-231 cell electrotaxis and investigation of its underlying signaling mechanisms will lead to a better understanding of electrically guided cancer cell migration and metastasis. Therefore, we quantitatively characterized MDA-MB-231 cell electrotaxis and a few associated signaling events. Using a microfluidic device that can create well-controlled dcEF, we showed the anode-directing migration of MDA-MB-231 cells. In addition, surface staining of epidermal growth factor receptor (EGFR) and confocal microscopy showed the dcEF-induced anodal EGFR polarization in MDA-MB-231 cells. Furthermore, we showed an increase of intracellular calcium ions in MDA-MB-231 cells upon dcEF stimulation. Altogether, our study provided quantitative measurements of electrotactic migration of MDA-MB-231 cells, and demonstrated the electric field-mediated EGFR and calcium signaling events, suggesting their involvement in breast cancer cell electrotaxis.     

Distinct Regulation of Cytoplasmic Calcium Signals and Cell Death Pathways by Different Plasma Membrane Calcium ATPase Isoforms in MDA-MB-231 Breast Cancer Cells

Plasma membrane calcium ATPases (PMCAs) actively extrude Ca(2+) from the cell and are essential components in maintaining intracellular Ca(2+) homeostasis. There are four PMCA isoforms (PMCA1-4), and alternative splicing of the PMCA genes creates a suite of calcium efflux pumps. The role of these different PMCA isoforms in the control of calcium-regulated cell death pathways and the significance of the expression of multiple isoforms of PMCA in the same cell type are not well understood. In these studies, we assessed the impact of PMCA1 and PMCA4 silencing on cytoplasmic free Ca(2+) signals and cell viability in MDA-MB-231 breast cancer cells. The PMCA1 isoform was the predominant regulator of global Ca(2+) signals in MDA-MB-231 cells. PMCA4 played only a minor role in the regulation of bulk cytosolic Ca(2+), which was more evident at higher Ca(2+) loads. Although PMCA1 or PMCA4 knockdown alone had no effect on MDA-MB-231 cell viability, silencing of these isoforms had distinct consequences on caspase-independent (ionomycin) and -dependent (ABT-263) cell death. PMCA1 knockdown augmented necrosis mediated by the Ca(2+) ionophore ionomycin, whereas apoptosis mediated by the Bcl-2 inhibitor ABT-263 was enhanced by PMCA4 silencing. PMCA4 silencing was also associated with an inhibition of NFκB nuclear translocation, and an NFκB inhibitor phenocopied the effects of PMCA4 silencing in promoting ABT-263-induced cell death. This study demonstrates distinct roles for PMCA1 and PMCA4 in the regulation of calcium signaling and cell death pathways despite the widespread distribution of these two isoforms. The targeting of some PMCA isoforms may enhance the effectiveness of therapies that act through the promotion of cell death pathways in cancer cells.     

Bacterial O-Methylation of Chloroguaiacols: Effect of Substrate Concentration, Cell Density, and Growth Conditions

O-methylation of chloroguaiacols has been examined in a number of gram-positive and gram-negative bacteria to elucidate the effects of substrate concentration, growth conditions, and cell density. Substrate concentrations between 0.1 and 20.0 mg liter⁻¹ were used, and it was found that (i) yields of the O-methylated products were significantly higher at the lowest concentrations and (ii) rates of O-methylation were not linear functions of concentration. With 3,4,5-trichloroguaiacol, the nature of the metabolites also changed with concentration. During growth with a range of substrates, O-methylation of chloroguaiacols also took place. With vanillate, however, de-O-methylation occurred: the chlorocatechol formed from 4,5,6-trichloroguaiacol was successively O-methylated to 3,4,5-trichloroguaiacol and 3,4,5-trichloroveratrole, whereas that produced from 4,5-dichloroguaiacol was degraded without O-methylation. Effective O-methylation in nonproliferating suspensions occurred at cell densities as low as 10⁵ cells ml⁻¹, although both the yields and the rates were lower than in more dense cultures. By using disk assays, it was shown that, compared with their precursors, all of the O-methylated metabolites were virtually nontoxic to the strains examined. It is therefore proposed that O-methylation functions as a detoxification mechanism for cells exposed to chloroguaiacols and chlorophenols. In detail, significant differences were observed in the response of gram-positive and gram-negative cell strains to chloroguaiacols. It is concluded that bacterial O-methylation is to be expected in the natural environment subjected to discharge of chloroguaiacols.     

Signal-Dependent Control of Autophagy and Cell Death in Colorectal Cancer Cell: The Role of the p38 Pathway

Autophagy is a vacuolar process leading to the degradation of long-lived proteins and cytoplasmic organelles in eukaryotes. This process has an important role in normal and cancer cells during adaptation to changing environmental conditions, cellular and tissue remodeling, and cell death.

To date, several signaling cascades have been described to regulate autophagy in a cell type-specific and signal-dependent manner.

We found that pharmacological blockade of the p38 pathway in colorectal cancer cells, either by the inhibitor SB202190 or by genetic ablation of p38α kinase, causes cell cycle arrest and autophagic cell death. In these cells, a complex network of intracellular kinase cascades controls autophagy and survival since the effect of p38α blockade is differentially affected by the pharmacological inhibition of MEK1, PI3K class I and III, and mTOR or by the differentiation status.

Collectively, our results suggest an opportunity for exploiting the pharmacological manipulation of the p38α pathway in the treatment of colorectal cancer. Given the number of drugs, currently available or under development, that target the p38 pathway, it stands to reason that elucidating the molecular mechanisms that link p38 and autophagy might have an impact on the clinical translation of these drugs.

Addendum to:

A Novel Cell Type-Specific Role of p38α in the Control of Autophagy and Cell Death in Colorectal Cancer Cells

F. Comes, A. Matrone, P. Lastella, B. Nico, F.C. Susca, R. Bagnulo, G. Ingravallo, S. Modica, G. Lo Sasso, A. Moschetta, G. Guanti and C. Simone

Cell Death Differ 2007; 14: 693-702     

Regulation of Cell Cytoskeleton and Membrane Mechanics by Electric Field: Role of Linker Proteins

Cellular mechanics is known to play an important role in the cell homeostasis including proliferation, motility, and differentiation. Significant variation in the mechanical properties between different cell types suggests that control of the cell metabolism is feasible through manipulation of the cell mechanical parameters using external physical stimuli. We investigated the electrocoupling mechanisms of cellular biomechanics modulation by an electrical stimulation in two mechanically distinct cell types—human mesenchymal stem cells and osteoblasts. Application of a 2 V/cm direct current electric field resulted in approximately a twofold decrease in the cell elasticity and depleted intracellular ATP. Reduction in the ATP level led to inhibition of the linker proteins that are known to physically couple the cell membrane and cytoskeleton. The membrane separation from the cytoskeleton was confirmed by up to a twofold increase in the membrane tether length that was extracted from the cell membrane after an electrical stimulation. In comparison to human mesenchymal stem cells, the membrane-cytoskeleton attachment in osteoblasts was much stronger but, in response to the same electrical stimulation, the membrane detachment from the cytoskeleton was found to be more pronounced. The observed effects mediated by an electric field are cell type- and serum-dependent and can potentially be used for electrically assisted cell manipulation. An in-depth understanding and control of the mechanisms to regulate cell mechanics by external physical stimulus (e.g., electric field) may have great implications for stem cell-based tissue engineering and regenerative medicine.     

Effect of pH, Protein Concentration, and Ionic Strength on Heat Inactivation of Staphylococcal Enterotoxin B

Heat treatment of highly purified staphylococcal enterotoxin B causes a more rapid loss of immunological activity at 70 to 80 C than at 90 to 100 C. Toxicological results based on intravenous injection of dogs paralleled the results obtained by immunological means (single gel diffusion). The loss of immunological activity did not follow first-order kinetics. Results are given on the effects on heat inactivation of changing pH, ionic strength, and initial concentration of enterotoxin. Disc-gel electrophoresis of purified enterotoxin B showed a major and minor band. The minor band was a size isomer of the major band.     

The Relative Concentration of Solids in the Nucleolus, Nucleus, and Cytoplasm of the Developing Nerve Cell of the Chick

Growing and differentiating nerve cells of the fifth cranial ganglion of the chick embryo were studied by several means. During the period of 70 hours to 11 days of incubation (Hamburger-Hamilton stages 19 to 37) average cell mass increased more than 4.5 times while cells changed from relatively undifferentiated neuroblasts to morphologically characteristic nerve cells with long processes. By making simplifying assumptions about thickness of nucleus and nucleolus, relative to cytoplasmic thickness, it was possible to calculate solute concentration of nucleus and nucleolus relative to that of the cytoplasm from measurements of optical retardations through living cells. Differences in relative solute concentration were observed in nucleolus, cytoplasm, and nucleoplasm in the approximate ratio 1.2:1.0:0.8, respectively. The ratio remained essentially constant during the growth period examined despite the fact that the cell components grow at markedly different rates. This suggests that solid concentrations are physical characteristics of nucleus, nucleolus, and cytoplasm which are maintained even during rapid growth and differentiation. By cytochemical means it was demonstrated that mass increase in the nucleus is not associated with increase in deoxyribonucleic acid. Both ribonucleic acid and protein are in greater concentration in nucleolus and cytoplasm than in the nucleoplasm. Electron microscopy shows interruptions in the nuclear envelope as well as an approximately even distribution of electron density in nucleus and cytoplasm. It is pointed out that consistent differences in solid concentration can exist on either side of the nuclear envelope even though it contains "pores." Implications of these data are discussed.     

Regulation of Mammalian Cell Growth and Death by Bacterial Redox Proteins: Relevance to Ecology and Cancer Therapy

Recent evidence indicates that bacterial redox proteins such as cupredoxins andcytochromes, that are normally involved in electron transfer during respiration, can entermammalian cells and induce either apoptosis or inhibition of cell cycle progression. Suchproteins have also been shown to demonstrate a good deal of specificity for entry andinduction of cytotoxic effects in cancer cells, allowing both in vitro cell death and in vivoinhibition of cancer progression. An alteration in the hydrophobicity of the bacterial redoxproteins can lead to a switch from apoptosis to growth arrest and vice versa throughmodulation of the intracellular levels of tumor suppressors. The preferential entry andcytotoxicity of these redox proteins in cancer cells raises interesting questions about thepresence of other bacterial proteins that may affect cell cycle at the G2/M phase, therebypotentially arresting cancer growth. The intracellular localization of the bacterial redoxproteins in nonpathogenic soil bacteria similarly raises questions about their possible rolein allowing various nonpathogenic soil bacteria to defend themselves from environmentalpredators by inducing cytotoxicity when engulfed in large numbers. A new role of theredox proteins in soil bacteria in maintaining an ecological balance among the predatorsand preys is proposed.