Involvement of reactive oxygen species in capsaicinoid-induced apoptosis in transformed cells

Some varieties of sweet pepper accumulate non-pungent isosters of capsaicin, a type of compounds exemplified by capsiate. The only structural difference between capsaicin and capsiate is the link between the vanillyl and the acyl moieties, via an amide bond in the former and via an ester bond in the latter. By flow cytometry analyses we have determined that nor-dihydrocapsiate, a simplified analogue of capsiate, is a pro-oxidant compound that induces apoptosis in the Jurkat tumor cell line. The nuclear DNA fragmentation induced by nor-dihydrocapsiate is preceded by an increase in the production of reactive oxygen species and by a subsequent disruption of mitochondria transmembrane potential. Capsiate-induced apoptosis is initiated at the S phase of the cell cycle and is mediated by a caspase-3-dependent pathway. The accumulation of intracellular reactive oxygen species in capsiate-treated cells is greatly prevented by the presence of ferricyanide, suggesting that capsiates target a cellular redox system distinct from the one involved in the mitochondrial electron-chain transport. Methylation of the phenolic hydroxyl of nor-dihydrocapsiate completely abrogated the ability to induce reactive oxygen species and apoptosis, highlighting the relevance of the presence of a free phenolic hydroxyl for the pro-oxidant properties of capsaicinoids.     

Role of reactive oxygen species (ROS) in apoptosis induction

Reactive oxygen species (ROS) and mitochondria play an important role in apoptosis induction under both physiologic and pathologic conditions. Interestingly, mitochondria are both source and target of ROS. Cytochrome c release from mitochondria, that triggers caspase activation, appears to be largely mediated by direct or indirect ROS action. On the other hand, ROS have also anti-apoptotic effects. This review focuses on the role of ROS in the regulation of apoptosis, especially in inflammatory cells.     

The role of reactive oxygen species in apoptosis of the diabetic kidney

Increased levels of reactive oxygen species (ROS) by hyperglycemia can induce apoptosis of renal cells and diabetic nephropathy. The redox balance in the renal cell seems, therefore, of the utmost importance. ROS-mediated apoptosis may be further aggravated by an inadequate cytoprotective response against ROS. When there are insufficient cytoprotective and ROS scavenging molecules, ROS lead to considerable cellular damage and to a point of no return in apoptosis. Induction of cytoprotective proteins may prevent or attenuate apoptosis, renal cell injury, and finally diabetic nephropathy. Here, we discuss some mechanisms of apoptosis and several strategies that have been probed to ameliorate, or to prevent apoptosis in the diabetic kidney.     

Se-methylselenocysteine induces apoptosis mediated by reactive oxygen species in HL-60 cells

Recent studies have implicated apoptosis as one of the most plausible mechanisms of the chemopreventive effects of selenium compounds, and reactive oxygen species (ROS) as important mediators in apoptosis induced by various stimuli. In the present study, we demonstrate that Se-methylselenocysteine (MSC), one of the most effective selenium compounds at chemoprevention, induced apoptosis in HL-60 cells and that ROS plays a crucial role in MSC-induced apoptosis. The uptake of MSC by HL-60 cells occurred quite early, reaching the maximum within 1 h. The dose-dependent decrease in cell viability was observed by MSC treatment and was coincident with increased DNA fragmentation and sub-G(1) population. 50 microM of MSC was able to induce apoptosis in 48% of cell population at a 24 h time point. Moreover, the release of cytochrome c from mitochondria and the activation of caspase-3 and caspase-9 were also observed. The measurement of ROS by dichlorofluorescein fluorescence revealed that dose- and time-dependent increase in ROS was induced by MSC. N-acetylcysteine, glutathione, and deferoxamine blocked cell death, DNA fragmentation, and ROS generation induced by MSC. Moreover, N-acetylcysteine effectively blocked caspase-3 activation and the increase of the sub-G(1) population induced by MSC. These results imply that ROS is a critical mediator of the MSC-induced apoptosis in HL-60 cells.     

The influence of calcium and reactive oxygen species on influenza virus-induced apoptosis

In previous studies we observed that influenza A and B viruses induce apoptosis in Madin-Darby canine kidney (MDCK) cells and that this apoptosis is blocked by expression of bcl-2. Using a well-characterized, highly virulent, avian influenza virus, A/Turkey/Ontario/7732/66 (H5N9) (Ty/Ont), we sought to better understand this system. We investigated the influence of two cellular factors that are known to function in other models of apoptosis inhibited by bcl-2, calcium (Ca(2+)) and reactive oxygen species (ROS). Although Ca(2+) chelators generally inhibit apoptosis, treatment of MDCK cells with either an extracellular chelator, EGTA, or an intracellular chelator, BAPTAAM, induced apoptosis instead and enhanced Ty/Ont-induced apoptosis. Conversely, treatment with an ionophore, ionomycin, blocked the viral-induced apoptosis. In terms of ROS, neither treatment with antioxidants, N(2) flushing to induce hypoxia, nor nigericin (a compound which, like bcl-2, stabilizes the mitochondrial membrane potential against the effects of ROS and subsequent Ca(2+) dysregulation) were able to block Ty/Ont-induced apoptosis. Therefore, it is likely that ROS play little, if any, role in influenza-induced apoptosis in MDCK cells and the influence of Ca(2+) appears to be opposite to that in the majority of other more classical models of apoptosis.     

Thyroxine enhancement and the role of reactive oxygen species in tadpole tail apoptosis

Our objective is to clarify the role of reactive oxygen species (ROS) in the atrophying tail of anuran tadpoles (tail apoptosis). Changes in catalase, superoxide dismutase (SOD) and caspase activity, genomic DNA, and nitric oxide (NO) generation were investigated biochemically using Rana japonica tadpole tails undergoing regression during thyroid hormone enhancement. DNA fragmentation and ladder formation with concomitant shortening of tadpole tail were induced by DL-thyroxine (T4) in culture medium. Catalase activity was also decreased by T4 treatment. T4 was also found to increase NO synthase (NOS) activity in cultured tadpole tail with concomitant increase in the concentration of NO2- plus NO3- (NOx) in the culture medium. Additional treatment with N-monomethyl-L-arginine (NMMA), a potent inhibitor of NOS, suppressed the enhancing effects of T4 on tail shortening and catalase activity reduction. It was also found that treatment with isosorbide dinitrate (ISDN), a NO generating drug, alone also had an enhancing effect on tail shortening and catalase activity reduction similar to that seen with T4. Both NO and an NO donor (ISDN) strongly suppressed catalase activity. Kinetic analysis revealed that catalase activity decreased and caspase-3-like activity increased during normal tadpole tail atrophy (apoptosis). These results suggested that T4 enhances NO generation, thereby strongly inhibiting catalase activity, resulting in an increase in hydrogen peroxide, and that the oxidative stress elicited by excess hydrogen peroxide might activate cysteine-dependent aspartate-directed protease-3 (caspase-3-like protease), which is thought to cause DNA fragmentation, leading to apoptosis.     

Regulation of T-cell apoptosis by reactive oxygen species

To ensure that a constant number of T cells are preserved in the peripheral lymphoid organs, the production and proliferation of T cells must be balanced out by their death. Newly generated T cells exit the thymus and are maintained as resting T cells. Transient disruption of homeostasis occurs when naïve T cells undergo antigen-induced expansion, a process involving intracellular signaling events that lead to T cell proliferation, acquisition of effector functions, and, ultimately, either apoptosis or differentiation into long-lived memory cells. The last decision point (death vs. differentiation) is a crucial one: it resets lymphoid homeostasis, promotes protective immunity, and limits autoimmunity. Despite its importance, relatively little is known about the molecular mechanisms involved in this cell fate decision. Although multiple mechanisms are likely involved, recent data suggest an underlying regulatory role for reactive oxygen species in controlling the susceptibility of T cells to apoptosis. This review focuses on recent advances in our understanding of how reactive oxygen species modulate T-cell apoptosis.     

JNK activation limits dendritic cell maturation in response to reactive oxygen species by the induction of apoptosis

Dendritic cells (DC) sense infection in their local microenvironment and respond appropriately in order to induce T cell immunity. This response is mediated in part via the mitogen-activated protein kinase (MAPK) pathways. Hydrogen peroxide is present frequently in the inflammatory DC milieu and is known to activate MAPK. Therefore this study examines the role of hydrogen peroxide, both alone and in combination with lipopolysaccharide (LPS), in the regulation of activation of two key MAPK, p38 and JNK, regulation of phenotype, and regulation of apoptosis in human monocyte-derived DC. At low concentrations, hydrogen peroxide activates p38, but does not alter DC phenotype. At higher concentrations, hydrogen peroxide activates both p38 and JNK. Activation of JNK, which is associated with inhibition of tyrosine phosphatases in DC, is linked to the induction of DC apoptosis. An upstream JNK inhibitor (CEP11004) and a competitive JNK inhibitor (SP600125) both partially protected the DC from the proapoptotic effects of hydrogen peroxide. Unexpectedly, hydrogen peroxide and LPS synergize in inducing JNK activation and DC apoptosis. JNK-mediated apoptosis may limit damaging immune responses against neoepitopes generated by modification of self-antigens by reactive oxygen species present at sites of inflammation.     

ASK1 is activated by arsenic trioxide in leukemic cells through accumulation of reactive oxygen species and may play a negative role in induction of apoptosis

Arsenic trioxide (ATO) is remarkably effective for treating acute promyelocytic leukemia. Here, we find that ATO treatment of NB4 and K562 leukemic cells induces activation of ASK1. ASK1 activation was induced most significantly at low concentrations of ATO, where G2/M arrest but not apoptosis was induced. On the other hand, ATO barely activated ASK1 at high concentrations, where apoptosis as well as activation of JNK and p38 was induced significantly. ATO-induced accumulation of reactive oxygen species (ROS), while the ASK1 activation was suppressed by cotreatment with an antioxidant, N-acetyl-l-cysteine. Murine embryonic fibroblasts (MEFs) from ASK1-deficient mice were more susceptible to ATO-induced apoptosis than control MEFs. Furthermore, ATO at the low concentration induced significant apoptosis in K562 cells when ASK1 was knocked down by siRNA. These results indicate that ASK1 is activated by ATO through ROS accumulation and may negatively regulate apoptosis in leukemic cells without activating p38 and JNK.     

Pyrrolidinium-type fullerene derivative-induced apoptosis by the generation of reactive oxygen species in HL-60 cells

The biological activities of C₆₀-bis(N,N-dimethylpyrrolidinium iodide), a water-soluble cationic fullerene derivative, on human promyeloleukaemia (HL-60) cells were investigated. The pyrrolidinium fullerene derivative showed cytotoxicity in HL-60 cells. The characteristics of apoptosis, such as DNA fragmentation and condensation of chromatin in HL-60 cells, were observed by exposure to the pyrrolidinium fullerene derivative. Caspase-3 and -8 were activated and cytochrome c was also released from mitochondria. The generation of reactive oxygen species (ROS) by the pyrrolidinium fullerene derivative was observed by DCFH-DA, a fluorescence probe for the detection of ROS. Pre-treatment with α-tocopherol suppressed cell death and intracellular oxidative stress caused by the pyrrolidinium fullerene derivative. The apoptotic cell death induced by the pyrrolidinium fullerene derivative was suggested to be mediated by ROS generated by the pyrrolidinium fullerene derivative.     

Beryllium-stimulated reactive oxygen species and macrophage apoptosis

Beryllium (Be), the etiologic agent of chronic beryllium disease, is a toxic metal that induces apoptosis in human alveolar macrophages. We tested the hypothesis that Be stimulates the formation of reactive oxygen species (ROS) which plays a role in Be-induced macrophage apoptosis. Mouse macrophages were exposed to 100 microM BeSO4 in the absence and presence of the catalytic antioxidant MnTBAP (100 microM). Apoptosis was measured as the percentage of TUNEL+ and caspase-8+ cells. ROS production was measured by flow cytometry using the fluorescence probes, dihydroethidine (DHE) and dichlorofluorescein diacetate (DCFH-DA). Be-exposed macrophages had increased TUNEL+ cells (15+/-1% versus controls 1+/-0.2%, P<0.05) and increased caspase-8+ cells (18.7+/-2% versus controls 1.8+/-0.4%, P<0.05). Be-induced caspase-8 activation, and a 4-fold increase in ROS formation, was ameliorated by exposure to MnTBAP. Hydrogen peroxide (30 microM) exposure potentiated Be-induced caspase-8 activation, and was also attenuated by MnTBAP. Our data are the first to demonstrate that Be stimulates macrophage ROS formation which plays an important role in Be-induced macrophage apoptosis.     

Arsenite induces apoptosis in chinese hamster ovary cells by generation of reactive oxygen species

Arsenic, a human carcinogen, possesses a serious environmental threat but the mechanism of its toxicity remains unclear. Knowledge of how arsenic induces cell death and how cells escape the death path may help to understand arsenic carcinogenesis. We have investigated the nature of sodium arsenite-induced cell death in Chinese hamster ovary K1 cells. Following phosphate-citric acid buffer extraction, apoptotic cells with lower DNA content than the G1 cells were detected by flow cytometry. Immediately after 4 h of 40 μM arsenite treatment, no appreciable fraction of cells with sub-G1 DNA content was detected; however, the sub-G1 cell fraction increased with postarsenite incubation time, and detectable increase started at 8 h of incubation, whereas the intracellular peroxide level as measured by the fluorescent intensity of 2′,7′-dichlorofluorescein increased immediately following a 4-h arsenite treatment. Simultaneous treatment with arsenite plus antioxidant (N-acetyl-cysteine, Trolox, and Tempo); copper ion chelator (neocuproine); protein kinase inhibitor (H-7) or protein synthesis inhibitor (cycloheximide) reduced the fraction of sub-G1 cell and internucleosomal DNA degradation. Trolox, neocuproine, or cycloheximide given after arsenite treatment also effectively reduced apoptosis. These results lead to a working hypothesis that arsenite-induced apoptosis in CHO-K1 cells is triggered by the generation of hydrogen peroxide, followed by a copper-mediated Fenton reaction that catalyzes the production of hydroxyl radicals, which selectively activates protein kinase through de novo synthesis of macromolecules. © 1996 Wiley-Liss, Inc.     

Signaling and proapoptotic functions of transformed cell-derived reactive oxygen species

Transformed fibroblasts generate extracellular superoxide anions through the recently identified membrane-associated NADPH oxidase. These cell-derived superoxide anions exhibit signaling functions such as regulation of proliferation and maintenance of the transformed state. Their dismutation product hydrogen peroxide regulates the intracellular level of catalase, whose activity has been observed to be upregulated in certain transformed cells. After glutathione depletion, transformed cell-derived reactive oxygen species (ROS) exhibit apoptosis-inducing potential through the metal-catalyzed Haber-Weiss reaction. Moreover, transformed cell-derived ROS represent key elements for selective and efficient apoptosis induction by natural antitumor systems (such as fibroblasts, granulocytes and macrophages). These effector cells release peroxidase, which utilizes target cell-derived hydrogen peroxide for HOCl synthesis. In a second step, HOCl interacts with target cell-derived superoxide anions and forms apoptosis-inducing hydroxyl radicals. In a parallel signaling pathway, effector cell-derived NO interacts with target cell-derived superoxide anions and generates the apoptosis inducer peroxynitrite. Therefore, transformed cell-derived ROS determine transformed cells as selective targets for induction of apoptosis by these effector systems. It is therefore proposed that transformed cell derived ROS interact with associated cells to exhibit directed and specific signaling functions, some of which are beneficial and some of which can become detrimental to transformed cells.     

Restraining reactive oxygen species in Listeria monocytogenes promotes the apoptosis of glial cells

Objectives: Listeria monocytogenes is a facultative anaerobic foodborne pathogen that can traverse the blood–brain barrier and cause brain infection. L. monocytogenes infection induces host cell apoptosis in several cell types. In this study, we investigated the apoptosis of human glioma cell line U251 invaded by L. monocytogenes and evaluated the function of bacterial reactive oxygen species (ROS) during infection.

Methods: Bacterial ROS level was reduced by carrying out treatment with N-acetyl cysteine (NAC) and diphenyleneiodonium chloride (DPI). After infection, the apoptosis of U251 cells was examined by flow cytometry assay and propidium iodide staining.

Results: DPI and NAC efficiently decreased ROS level in L. monocytogenes without affecting bacterial growth. Moreover, the apoptosis of glial cells was enhanced upon invasion of DPI- and NAC-pretreated L. monocytogenes.

Discussion: Results indicate that the apoptosis of glial cells can be induced by L. monocytogenes, and that the inhibition of bacterial ROS increases the apoptosis of host cells.     

Pivotal role of reactive oxygen species as intracellular mediators of hyperthermia-induced apoptosis

The effects of cellular antioxidant capacity on hyperthermia (HT)-induced apoptosis and production of antiapoptotic heat shock proteins (HSPs) were investigated in HL-60 cells and in HL-60AR cells that are characterized by an elevated endogenous catalase activity. Exposure of both cell lines to 43 degrees C for 1 h initiated apoptosis. Apoptosis peaked at 3-6 h after heat exposure in the HL-60 cells. Whereas HL-60AR cells were partially protected against HT-induced apoptosis at these early time points, maximal levels of apoptosis were detected later, i.e. 12-18 h after heat exposure. This differential induction of apoptosis was directly correlated to the induction of the antiapoptotic HSP27 and HSP70. In particular, in the HL-60 cells HSP27 was significantly induced at 12-18 h after exposure to 43 degrees C when apoptosis dropped. In contrast, coinciding with the late onset of apoptosis in HL-60AR cells at that time HL-60AR cells lacked a similar HSP response. In line with the higher antioxidant capacity HL-60AR cells accumulated reactive oxygen species to a lesser degree than HL-60 cells after heat treatment. Protection from HT-induced apoptosis as well as diminished heat-induced HSP27 expression was also observed after cotreatment of HL-60 cells with 43 degrees C and catalase but not with superoxide dismutase. These data emphasize the pivotal role of reactive oxygen species for HT induced pro- and antiapoptotic pathways.     

Withaferin A-induced apoptosis in human breast cancer cells is mediated by reactive oxygen species

Withaferin A (WA), a promising anticancer constituent of Ayurvedic medicinal plant Withania somnifera, inhibits growth of MDA-MB-231 and MCF-7 human breast cancer cells in culture and MDA-MB-231 xenografts in vivo in association with apoptosis induction, but the mechanism of cell death is not fully understood. We now demonstrate, for the first time, that WA-induced apoptosis is mediated by reactive oxygen species (ROS) production due to inhibition of mitochondrial respiration. WA treatment caused ROS production in MDA-MB-231 and MCF-7 cells, but not in a normal human mammary epithelial cell line (HMEC). The HMEC was also resistant to WA-induced apoptosis. WA-mediated ROS production as well as apoptotic histone-associated DNA fragment release into the cytosol was significantly attenuated by ectopic expression of Cu,Zn-superoxide dismutase in both MDA-MB-231 and MCF-7 cells. ROS production resulting from WA exposure was accompanied by inhibition of oxidative phosphorylation and inhibition of complex III activity. Mitochondrial DNA-deficient Rho-0 variants of MDA-MB-231 and MCF-7 cells were resistant to WA-induced ROS production, collapse of mitochondrial membrane potential, and apoptosis compared with respective wild-type cells. WA treatment resulted in activation of Bax and Bak in MDA-MB-231 and MCF-7 cells, and SV40 immortalized embryonic fibroblasts derived from Bax and Bak double knockout mouse were significantly more resistant to WA-induced apoptosis compared with fibroblasts derived from wild-type mouse. In conclusion, the present study provides novel insight into the molecular circuitry of WA-induced apoptosis involving ROS production and activation of Bax/Bak.     

Mechanical traumatic injury without circulatory shock causes cardiomyocyte apoptosis: role of reactive nitrogen and reactive oxygen species

Apoptotic cell death plays a critical role in tissue injury and organ dysfunction under a variety of pathological conditions. The present study was designed to determine whether apoptosis may contribute to posttraumatic cardiac dysfunction, and if so, to investigate the mechanisms involved. Male adult mice were subjected to nonlethal traumatic injury, and cardiomyocyte apoptosis, cardiac function, and cardiac production of reactive oxygen/nitrogen species were determined. Modified Noble-Collip drum trauma did not result in circulatory shock, and the 24-h survival rate was 100%. No direct mechanical traumatic injury was observed in the heart immediately after trauma. However, cardiomyocyte apoptosis gradually increased and reached a maximal level 12 h after trauma. Significantly, cardiac dysfunction was observed 24 h after trauma in the isolated perfused heart. This was completely reversed when apoptosis was blocked by administration of a nonselective caspase inhibitor immediately after trauma. In the traumatized hearts, reactive nitrogen species (e.g., nitric oxide) and reactive oxygen species (e.g., superoxide) were both significantly increased, and maximal nitric oxide production preceded maximal apoptosis. Moreover, a highly cytotoxic reactive species, peroxynitrite, was markedly increased in the traumatic heart, and there was a significant positive correlation between cardiac nitrotyrosine content and caspase 3 activity. Our present study demonstrated for the first time that nonlethal traumatic injury caused delayed cell death and that apoptotic cardiomyocyte death contributes to posttrauma organ dysfunction. Antiapoptotic treatments, such as blockade of reactive nitrogen oxygen species generation, may be novel strategies in reducing posttrauma multiple organ failure.     

Polymorphonuclear leukocytes modulate tissue factor production by mononuclear cells: role of reactive oxygen species

To determine whether polymorphonuclear leukocytes (PMN) modulate the production of tissue factor (TF) by monocytes, PBMC were incubated with increasing concentrations of PMN. PMN did not express any procoagulant activity. After 20-h cocultures, PMN enhanced or inhibited the TF production of PBMC, and this effect depended on the PMN/PBMC ratio. When the ratio increased from 1/1000 to 1/5, without or with LPS, the TF activity of PBMC increased to peak at 2.5-fold the baseline value (p < 0.01). The TF Ag and TF mRNA also increased. This potentiating effect was mediated by reactive oxygen species (ROS) released by PMN during the coculture; it did not require direct cell contact between PMN and PBMC, it was enhanced when PMN were stimulated by fMLP (a chemotactic peptide), and it was inhibited by two antioxidants, N-acetyl cysteine and pyrrolidine dithiocarbamate. In contrast, when the PMN/PBMC ratio was further increased from 1/2 to 2/1, the PBMC TF activity, Ag, and mRNA decreased and were inhibited compared with those of PBMC cultured alone (p < 0.01). This inhibitory effect required direct cell contact between PMN and PBMC, and it was not due to a PMN-mediated cytotoxicity. To confirm the role of ROS, H2O2 enhanced then inhibited the TF activity of PBMC in a dose-dependent manner, similarly to PMN. Thus, PMN may play an important role in the pathogenesis of thrombosis and atherosclerosis by exerting concentration-dependent regulatory effects on the TF production by PBMC via the release of ROS.     

The Participation of calcium ions and reactive oxygen species in the induction of antioxidant enzymes and heat resistance in plant cells by hydrogen sulfide donor

The effect of hydrogen sulfide (H₂S) donor sodium hydrosulfide (NaHS) on the heat resistance of wheat (Triticum aestivum L.) coleoptile cells, the formation of reactive oxygen species (ROS), and the activity of the antioxidant enzymes in them was investigated. The treatment of coleoptiles with 100 µM NaHS caused transient enhancement of the generation of the superoxide anion radical (O₂ ^?) and an increased hydrogen peroxide content. The activities of antioxidant enzymes—superoxide dismutase, catalase, and guaiacol peroxidase— and coleoptile resistance to damaging heat was later found to have increased. The biochemical and physiological effects of the hydrogen sulfide donor described above were inhibited by the treatment of wheat coleoptiles with the hydrogen peroxide scavenger dimethylthiourea, the NADPH oxidase inhibitor imidazole, the extracellular calcium chelator EGTA, and the phosphatidylinositol-specific phospholipase C inhibitor neomycin. A conclusion was made on the role of ROS generation, which is dependent on the activity of NADPH oxidase and calcium homeostasis, in the transduction of the H₂S signal, which induces antioxidant enzymes and the development of plant cell heat resistance.