Enhancement of redirected target cell lysis by cytotoxic T lymphocytes in the presence of cytochalasin B

The cytochalasins are known secretogogues. Their function as such is examined in light of the granule exocytosis model for lymphocyte-mediated cytotoxicity. Cytochalasin B is found to enhance target cell lysis by cytotoxic T lymphocytes when antibody-coated polystyrene beads are used to bridge the cells. The pattern of lysis is found to be biphasic in its dependence on cytochalasin B. Secretion of the enzyme BLT-esterase from the effector cells parallels the cytochalasin concentration-dependent pattern of lysis. Cytochalasin D is also able to enhance lysis but at concentrations less than cytochalasin B. Cytochalasin B does not inhibit binding of breads to the effector cell. This is shown by the ability of fluorescent beads coated with antibody to bind with an appropriate specificity to cells. These studies indicate that cytochalasin B is not strictly inhibitory for the induction of target cell lysis but can enhance lymphocyte-mediated lysis at low drug concentrations. These results are compatible with the interpretation that target cell lysis is mediated through a secretion process from cytotoxic T lymphocytes.     

Clq enhancement of IgG-dependent eosinophil-mediated killing of schistosomula in vitro

Antibody-dependent eosinophil-mediated cytotoxicity plays a role in host protection against metazoan parasite invasion. We examined a possible role for Clq in eosinophil-mediated cytotoxicity by using a Schistosoma mansoni schistosomula killing system in vitro. The addition of monomeric purified human Clq enhanced IgG-dependent human eosinophil-mediated killing from 1.4-fold to 2.3-fold (mean percent killing 12% +/- 4 vs 21% +/- 4, p less than 0.005) when the immune IgG concentration was low. In contrast, there was no significant enhancement of neutrophil-mediated killing. When the IgG concentration was increased fourfold Clq did not cause enhancement of eosinophil-mediated killing (35% +/- 9 vs 37% +/- 5). Preincubation of eosinophils with type 1 collagen abrogated Clq enhancement of killing, raising the possibility of a receptor-mediated process, which depends upon cellular binding of Clq via the collagenous portion of the molecule. Eosinophils and neutrophils were examined for the presence of Clq receptors by using 125I labeled Clq. Clq binding to both cell types was saturable, reversible, and specific, indicating that binding is through specific receptors. Type 1 collagen inhibited binding of Clq to cells, suggesting that Clq binding is via the collagenous stalk of Clq. The number of receptors was approximately twice as high for eosinophils as compared with neutrophils (1.9 X 10(7) vs 1.1 X 10(7), p less than 0.025). Affinity constants for the two cell types were similar (1.5 X 10(7) vs 1.3 X 10(7). These findings suggest that Clq and receptors for Clq on eosinophils may be important for eosinophil-mediated schistosomula killing.     

Response of adrenal tumor cells to adrenocorticotropin: site of inhibition by cytochalasin B.

The ability of cytochalasin B to inhibit the steroidogenic response of mouse adrenal tumor cells (Y-1) to adrenocorticotropin (ACTH) was examined with two aims: to consider the specificity of the inhibitor and to determine at what point(s) in the steroidogenic pathway it acts. Cytochalasin B did not inhibit protein synthesis or transport of [3H]-cholesterol into the cells nor did it alter total cell concentration of ATP. Together with previous evidence, this suggests that the effects of cytochalasin observed are relatively specific in these cells. Cytochalasin inhibits the increase in conversion of [3H]cholesterol to 20alpha-[3H]dihydroprogesterone (20alpha-hydroxypregn-4-en-3-one: a major product of the steroid pathway in Y-1 cells) produced by ACTH but does not inhibit conversion of cholesterol to pregnenolone by mitochondrial and purified enzyme preparations from Y-1 cells and bovine adrenal, respectively. Cytochalasin does not inhibit the conversion of pregnenolone to 20alpha-dihydroprogesterone but was shown to inhibit increased transport of [3H]cholesterol to mitochondria resulting from the action of ACTH. These findings indicate that cytochalasin acts after cholesterol has entered the cells and before it is subjected to side-chain cleavage in mitochondria. In view of the known action of cytochalasin on microfilaments, it is proposed that these organelles are necessary for the transport of cholesterol to the mitochondrial cleavage enzyme and that at least one effect of ACTH (and cyclic AMP) is exerted upon this transport process. The specificity of the effects of cytochalasin is considered in relation to this conclusion.     

Sensitivity of the proliferation of normal and tumor cells to cytochalasin D

The effect of cytochalasin D, which is known to disrupt specifically actin cytoskeleton, on DNA replication was studied. The incubation of cultured mouse embryonic fibroblasts (MEF), cells of Balb/3T3 line and cells of minimally transformed clones 12 MC and 6 st/T CAK-7 line with cytochalasin D leads to inhibition of DNA synthesis. A complete inhibition of labeled index in MEF culture was observed after an 8 day incubation in cytochalasin D. Part of cells of clones 12 MC and 6 st/T were insensitive to cytochalasin D and continued to enter to S-phase even after a 10 day incubation. The transfer of cells into a fresh medium leads to a rapid restoration of DNA synthesis. Strongly transformed L cells were almost insensitive to cytochalasin D. Thus, the reorganization of actin cytoskeleton caused by cytochalasin D can inhibit the cycle of normal and minimally transformed cells. In the course of neoplastic progression, in the transformed cells there is a loss of dependence of cell proliferation on microfilament system.     

Lectin-dependent neutrophil cytotoxicity: Enhanced susceptibility of desialylated red cells

Lectin-dependent neutrophil cytotoxicity against autologous human red cells was studied using an ¹¹¹In(indium)-release assay. Human red cells were not readily killed by neutrophils in the presence of phytohemagglutinin (PHA). However, removal of red cell membrane sialic acids (desialylation) markedly enhanced their susceptibility to PHA-dependent neutrophil cytotoxicity. This neutrophil cytotoxicity was dependent on the energy supplied by anaerobic glycolysis, but it was independent of erythrophagocytosis. Catalase, superoxide dismutase, KCN, and Na azide did not inhibit PHA-dependent neutrophil cytotoxicity. Neutrophils from a patient with chronic granulomatous disease, in the presence of PHA, also killed desialylated red cells normally. On the other hand, desialylation of neutrophils had no effect on the expression of their cytotoxic effect. The results suggest that desialylated red cells are much more susceptible to lectin-dependent neutrophil cytotoxicity than normal red cells, and that lectin-dependent neutrophil cytotoxicity is independent of reactive oxygen species.     

Toxicity of oxidized low-density lipoprotein to cultured fibroblasts is selective for S phase of the cell cycle

Oxidized LDL (o-LDL) is toxic to a variety of cultured cells. Preliminary results suggested that susceptibility is enhanced by cell proliferation. As a step toward determining the mechanism of cytotoxicity, we chose to identify the cell cycle phase(s) during which exposure of cultured human fibroblasts to o-LDL leads to death. Cytochalasin B, which blocks cell migration and proliferation, and irradiation, which prevents mitosis but not migration, both blocked cytotoxicity. Colchicine, which arrests cells in mitosis but does not inhibit DNA synthesis, did not block cytotoxicity. Treatment of cells with hydroxyurea, which blocks cells prior to S phase, prevented cell death. Addition of o-LDL to cells immediately after S phase allowed mitosis without death. The above results coupled with results using cells synchronized by three different means indicate that cell death is selective for proliferating cells and occurs after exposure to o-LDL during S phase. Understanding the mechanism of o-LDL-induced death may have implications for tissue damage in vivo in the numerous instances of pathology in which oxidized lipoproteins or lipids are present.     

Macrophage deformability and phagocytosis

The influence of several metabolic inhibitors and pharmacologic agents on macrophage deformation (induced by fluid shear stress) was examined in relationship to changes in ATP content and phagocytosis of latex beads. Two relatively specific inhibitors of glycolysis (iodoacetate [IA], and sodium fluoride [NaF]) and a sulfhydryl-binding agent (N-ethylmaleimide [NEM] markedly inhibited phagocytosis and reduced cell deformability. A microtubule-disrupting agent (vinblastine) and a highly specific inhibitor of glycolysis (2-deoxyglucose) markedly inhibited phagocytosis without influencing cell deformability. An organomercurial sulfhydryl binding agent p-chloromercuribenzene (PCMBS) and a microfilament-disrupting agent (cytochalasin B) inhibited phagocytosis and increased cell deformability. The effects of these agents on phagocytosis and cell deformability bore no consistent relationship to alterations in cellular content of ATP. The observation that 2-deoxyglucose, the most specific inhibitor of glycolysis examined, reduced ATP content to levels far lower (15 percent of control values) than those achieved by any other agent examined and inhibited phagocytosis without altering cell deformability, suggests that alterations in cell deformability induced by NaF, IA, NEM, PCMBS, and cytochalasin B are not due to inhibition of glycolysis per se, but instead result from direct or indirect effects of these agents on cell constituents, possibly contractile proteins, which are determinants of cell deformability. The finding that cytochalasin B, NEM, PCMBS, and IA interfere with phagocytosis and alter cell deformability, together with evidence that these agents interact with isolated actin and myosin, suggests that contractile proteins are important both in phagocytosis and as determinants of cell deformability. The observation that vinblastine, colchicines, and heavy water (D(2)O) did not alter cell deformability, even though vinblastine caused formation of intracellular crystals of microtubular protein, indicates that microtubules are not major determinants of cell deformability. The observations that beads adhered normally to surfaces of cytochalasin B- and of PCMBS-treated cells and that shear-stress induced deformation was increased whereas phagocytosis was markedly inhibited, suggest that deformation of cells around beads associated with ingestion depends on some form of cellular (contractile?) activity, whereas deformation of cells by fluid shear stress is a passive phenomenon.     

Induction of measles virus hemagglutinin in a persistently infected, nonvirogenic line of cells (BGM/MV).

BGM/MV cells carry measles virus antigens and nucleocapsid-like structures in their cytoplasm. There is no infectious virus demonstrable, and measles virus-induced cell surface changes detectable by hemadsorption (HAD) are absent. Treatment of cells with actinomycin D or cycloheximide or enucleation of cells with cytochalasin B induced surface changes in that the cells became HAD positive. 6-Azauridine treatment of cells did not inhibit the induction of HAD, suggesting that RNA synthesis was not required. Cycloheximide treatment of cells induced by enucleation inhibited the development of HAD, suggesting a requirement for protein synthesis.     

Tumor cell killing by macrophages activated in vitro with lymphocyte mediators. III. Inhibition by cytochalasins, colchicine, and vinblastine.

The effect of cytochalasin A and B, colchicine and vinblastine on tumor cell killing by macrophages activated in vitro with lymphocyte mediators was examined. Both cytochalasins reversibly inhibited the killing of tumor cells by activated macrophages. Kinetic studies with cytochalasin B suggested that this drug exerts its effect on an early step of the cytotoxic process. Additional studies revealed that the drug inhibited the binding of tumor cells by activated macrophages.Colchicine inhibited both the binding and the killing of tumor cells by activated macrophages, whereas its structural analogue, lumicolchicine, had no effect on either macrophage function.Vinblastine also inhibited the binding and killing of tumor cells. However, this drug no longer inhibited tumor cell binding at low concentrations (<10^?6M) that still inhibited tumor cell killing. Further, vinblastine inhibited tumor cell killing when added late to an ongoing cytolytic reaction.These results suggest that the cytochalasins, colchicine and vinblastine inhibit macrophage mediated cytotoxicity by preventing intimate contact between the effector macrophages and their targets. In addition, vinblastine also appears to inhibit a later step of the cytolytic process, possibly the secretion of a cytotoxic macrophage product.     

Pyridalyl inhibits cellular protein synthesis in insect, but not mammalian, cell lines

To gain insight into the mechanism of action and selectivity of the insecticidal activity of pyridalyl, the cytotoxicity of pyridalyl against various insect and mammalian cell lines was characterized by measuring the inhibition of cellular protein synthesis. When the effect of pyridalyl on the cellular protein synthesis in Sf9 cells was evaluated by measuring the incorporation of [(3)H]leucine, rapid and significant inhibition of protein synthesis was observed. However, pyridalyl did not inhibit protein synthesis in a cell-free protein synthesis system, indicating that pyridalyl does not directly inhibit protein synthesis. No obvious cytotoxicity was observed against any of the mammalian cell lines tested. In the case of insect cell lines, remarkable differences in the cytotoxicity of pyridalyl were observed: the highest cytotoxicity (IC50 mM) was found against Sf9 cells derived from Spodoptera frugiperda, whereas no obvious cytotoxicity was observed against BmN4 cells derived from Bombyx mori. Measurements of the insecticidal activity of pyridalyl against Spodoptera litura and B. mori revealed a correlation between the cytotoxicity against cultured cell lines and the insecticidal activity. From these observations, it was concluded that the selective inhibition of cellular protein synthesis by pyridalyl might contribute significantly to the insecticidal activity and the selectivity of this compound.     

Identification and analysis of the active phytochemicals from the anti-cancer botanical extract Bezielle

Bezielle is a botanical extract that has selective anti-tumor activity, and has shown a promising efficacy in the early phases of clinical testing. Bezielle inhibits mitochondrial respiration and induces reactive oxygen species (ROS) in mitochondria of tumor cells but not in non-transformed cells. The generation of high ROS in tumor cells leads to heavy DNA damage and hyper-activation of PARP, followed by the inhibition of glycolysis. Bezielle therefore belongs to a group of drugs that target tumor cell mitochondria, but its cytotoxicity involves inhibition of both cellular energy producing pathways. We found that the cytotoxic activity of the Bezielle extract in vitro co-purified with a defined fraction containing multiple flavonoids. We have isolated several of these Bezielle flavonoids, and examined their possible roles in the selective anti-tumor cytotoxicity of Bezielle. Our results support the hypothesis that a major Scutellaria flavonoid, scutellarein, possesses many if not all of the biologically relevant properties of the total extract. Like Bezielle, scutellarein induced increasing levels of ROS of mitochondrial origin, progressive DNA damage, protein oxidation, depletion of reduced glutathione and ATP, and suppression of both OXPHOS and glycolysis. Like Bezielle, scutellarein was selectively cytotoxic towards cancer cells. Carthamidin, a flavonone found in Bezielle, also induced DNA damage and oxidative cell death. Two well known plant flavonoids, apigenin and luteolin, had limited and not selective cytotoxicity that did not depend on their pro-oxidant activities. We also provide evidence that the cytotoxicity of scutellarein was increased when other Bezielle flavonoids, not necessarily highly cytotoxic or selective on their own, were present. This indicates that the activity of total Bezielle extract might depend on a combination of several different compounds present within it.     

Tumor cell killing by macrophages activated in vitro with lymphocyte mediators. IV. Role of energy metabolism

The role of energy metabolism on tumor cell killing by in vitro activated macrophages was studied. Depletion of extracellular glucose had little effect on the cytotoxic capacity of mediator-activated macrophages. Respiratory antagonists did not inhibit cytotoxicity regardless of whether or not the assays were carried out in low-glucose-containing medium. Sodium fluoride, a known inhibitor of glycolysis, inhibited the killing of tumor cells by activated macrophages. 2-Deoxyglucose, an analog of glucose, was found to be an effective inhibitor of cytotoxicity. Three other analogs, 5-thio-d-glucose, 3-O-methylglucose, and 2-deoxy-d-galactose, were without effect. The concentrations of 2-DG that inhibited cytotoxicity did not lower cellular ATP levels to an appreciable extent. The combined addition of inhibitors of glycolysis and respiration resulted in a marked reduction in ATP levels. Under these experimental conditions, macrophage-mediated cytotoxicity was also significantly inhibited.     

Inhibition of DNA synthesis in adrenocortical cells by cytochalasin B

ACTH inhibits DNA synthesis in normal rat and mouse tumor Y-1 adrenocortical cells within the same concentration range that it stimulates steroidogenesis. These processes can be independently regulated as demonstrated by the divergent actions of cytochalasin B on these cells. In the normal cells, cytochalasin B does not increase steroidogenesis in serum-free or serum-containing media, and it decreases the stimulation produced by ACTH. In the absence of serum, the Y-1 cells respond in a similar way. However, in serum-containing media, cytochalasin B increases steroidogenesis in these cells and does not inhibit the response to ACTH. In both cell types, cytochalasin B inhibits [3H]thymidine incorporation into DNA by a mechanism different than that of ACTH. In the Y-1 cells, this inhibition is caused by a decreased uptake of [3H]thymidine into the cell, which probably reflects a decreased transport across the cell membrane. In the normal cells, cytochalasin B, like ACTH, does not affect [3H]thymidine transport, but it decreases DNA synthesis much more rapidly than does ACTH. This inhibition may be the result of the disruption of microfilaments by cytochalasinB, because our evidence indicates that it is not caused by a decrease in glucose uptake by the cells.     

Effects of four agents that modify microtubules and microfilaments (vinblastine,colchicine, lidocaine,and cytochalasin B) on macrophage-mediated cytotoxicity to tumor cells

Summary The effects of vinblastine, colchicine, lidocaine, and cytochalasin B on tumor cell killing by BCG-activated macrophages were examined. These four drugs were selected for their action on membrane-associated cytoskeletal components, microtubules, and microfilaments. Colchicine and vinblastine, which block microtubular synthesis, inhibit macrophage-mediated tumor-cell cytotoxicity at a concentration of 10^–6 M. Cytochalasin B, which disrupts microfilaments, enhances tumor cell lysis and stasis due to activated macrophages at a concentration of 10^–7 M. Lidocaine, which may induce the disappearance of both microtubules and microfilaments, has the same inhibiting effect as vinblastine at a concentration of 5×10^–7 M. Whereas vinblastine and lidocaine seem to act on the macrophage itself, cytochalasin B exerts its effect predominantly on the tumor cell. These results suggest that microtubules and microfilaments play a role in the destruction of tumor cells by activated macrophages.     

The unveiling of the Warburg effect and the inscribed innovative approach to a radical non toxic anticancer therapy

The purpose of this research has been deciphering the Warburg paradox, the biochemical enigma unsolved since 1923. We solved it by demonstrating that its specific character, i.e. the forced aerobic lactate exportation, represents a crucial metabolic device to counteract the cytotoxic effect produced by an excess of pyruvate at the connection of glycolysis with the Krebs cycle. This solution was verified by exposing cancer cells of different histogenesis to pyruvate concentrations higher than the physiological ones, after showing that these concentrations are totally innocuous when injected into mice. The mechanism of the pyruvate cytotoxicity relies on the saturation of the respiratory chain, leading to a negative shift of the cytosolic NADP/NADPH ratio and the consequent restriction of the purine synthesis and the related cell apoptosis. The reducing equivalents generated by glycolysis and by cytosolic metabolism compete each other for their disposal trough the respiratory chain; this makes it that the cytotoxicity of pyruvate is inversely related to the mitochondrial number and efficiency of various cell types. Thus, the cytotoxicity is high in anaplastic cancer stem cells, whose mitochondria are extremely few and immature (cristae-poor); on the contrary, no inhibition is brought about in adult differentiated cells, physiologically rich of mature mitochondria. All this generates the pyruvate anticancer selectivity, together with the lack of a general toxicity, making pyruvate represent an ideal candidate for a radical non toxical anticancer treatment.     

Cytochalasin B: Its action on glucose-induced electrical and metabolic responses in rat pancreatic islets

Cytochalasin B was found to inhibit both glucose-induced spike activity and glucose utilization in isolated rat pancreatic islets under conditions previously shown to increase insulin release (Lacy, P.E., Klein N.J. and Fink. C.J. (1973) Endocrinology 92, 1458–1468). However, cytochalasin B did not prevent the depolarization of islet cells caused by high glucose. The results indicate that neither glycolysis nor spike activity are necessary events leading to insulin release.     

Importance of various types of metabolic inhibition for cell damage caused by direct membrane damage

Cell damage is caused by energy depletion or by direct membrane damage, or a combination when a direct membrane damage affects energy depleted cells. In this report it was investigated whether the extent of direct membrane damage induced by lysophosphatidyl choline (LPC) or phospholipase C (PhC) on quiescent fibroblasts depended on the metabolic state of the cells. When glycolysis was inhibited cell damage was always extensively increased, whereas cell damage was also increased to a minor degree when exposed to PhC during sole inhibition of oxidative phosphorylation. Acceleration of glycolysis in cells with a low rate of glycolysis resulted in a dramatic improvement of the membrane susceptibility within a few minutes. Thus, susceptibility of the cell membrane to direct membrane damage depends on the metabolic state. The results also emphasize previous findings that glycolysis has a special role in maintaining membrane function and integrity.     

Cytochalasin B induces cellular DNA fragmentation

Cellular DNA fragmentation can be induced in many biological instances without plasma membrane damage. The fungal metabolite, cytochalasin B, is capable of modifying numerous cellular functions related to DNA synthesis. In this work it is demonstrated that cytochalasin B is capable of inducing DNA fragmentation in a number of cells lines. This DNA fragmentation occurs before plasma membrane lysis and over a period of hours. Cytochalasin E and villin, agents that act on the microfilaments, also induce DNA fragmentation. Phorbol dibutyrate, a diacylglyceral analog, is able to inhibit cytochalasin B-induced DNA fragmentation in a dose-dependent fashion. These findings support the interpretation that cytochalasin B is inducing DNA fragmentation via its effect on the actin filaments.     

Polymorph-mediated antibody-dependent cytoxicity--modulation of activity by drugs and immune interferon.

Bovine polymorphonuclear leukocytes (PMN) mediated antibody-dependent cell cytotoxicity (ADCC) against erythrocyte and herpes virus-infected target cells. The extent of cytotoxicity was not affected by drugs that inhibited DNA, RNA, or protein synthesis. The effect did not occur in the absence of divalent cations, was suppressed by pretreatment of PMN with silica and cytochalasin B, and was subject to the bidirectional control by cyclic nucleotides; drugs decreasing cyclic AMP or elevating cyclic GMP levels enhanced ADCC. The ADCC phenomena was also enhanced by supernates containing immune interferon activity from antigen-stimulated-immune lymphocyte-macrophage cultures. The possibility that immune interferon(s) might be causing the elevation of ADCC and the relevance of this observation in terms of the part interferon might play in modulating recovery from herpes virus infections was discussed.