Anti-cancer effects of cerium oxide nanoparticles and its intracellular redox activity.

Data on medical applications of cerium oxide nanoparticles CeO2 (CONP) are promising, yet information regarding their action in cells is incomplete and there are conflicting reports about in vitro toxicity. Herein, we have studied cytotoxic effect of CONP in several cancer and normal cell lines and their potential to change intracellular redox status. The IC50 was achieved only in two of eight tested cell lines, melanoma 518A2 and colorectal adenocarcinoma HT-29. Self-propagating room temperature method was applied to produce CONP with an average crystalline size of 4 nm. The results confirmed presence of Ce(3+) and O(2-) vacancies. The induction of cell death by CONP and the production of reactive oxygen species (ROS) were analyzed by flow-cytometry. Free radicals related antioxidant capacity of the cells was studied by the reduction of stable free radical TEMPONE using electron spin resonance spectroscopy. CONP showed low or moderate cytotoxicity in cancer cell lines: adenocarcinoma DLD1 and multi-drug resistant DLD1-TxR, non-small cell lung carcinoma NCI-H460 and multi-drug resistant NCI-H460/R, while normal cell lines (keratinocytes HaCaT, lung fetal fibroblasts MRC-5) were insensitive. The most sensitive were 518A2 melanoma and HT-29 colorectal adenocarcinoma cell lines, with the IC50 values being between 100 and 200 µM. Decreased rate of TEMPONE reduction and increased production of certain ROS species (peroxynitrite and hydrogen peroxide anion) indicates that free radical metabolism, thus redox status was changed, and antioxidant capacity damaged in the CONP treated 518A2 and HT-29 cells. In conclusion, changes in intracellular redox status induced by CONP are partly attributed to the prooxidant activity of the nanoparticles. Further, ROS induced cell damages might eventually lead to the cell death. However, low inhibitory potential of CONP in the other human cell lines tested indicates that CONP may be safe for human usage in industry and medicine.

Irradiation induced injury reduces energy metabolism in small intestine of Tibet minipigs.

BACKGROUND: The radiation-induced energy metabolism dysfunction related to injury and radiation doses is largely elusive. The purpose of this study is to investigate the early response of energy metabolism in small intestinal tissue and its correlation with pathologic lesion after total body X-ray irradiation (TBI) in Tibet minipigs. METHODS AND RESULTS: 30 Tibet minipigs were assigned into 6 groups including 5 experimental groups and one control group with 6 animals each group. The minipigs in these experimental groups were subjected to a TBI of 2, 5, 8, 11, and 14 Gy, respectively. Small intestine tissues were collected at 24 h following X-ray exposure and analyzed by histology and high performance liquid chromatography (HPLC). DNA contents in this tissue were also examined. Irradiation causes pathologic lesions and mitochondrial abnormalities. The Deoxyribonucleic acid (DNA) content-corrected and uncorrected adenosine-triphosphate (ATP) and total adenine nucleotides (TAN) were significantly reduced in a dose-dependent manner by 2-8 Gy exposure, and no further reduction was observed over 8 Gy. CONCLUSION: TBI induced injury is highly dependent on the irradiation dosage in small intestine and inversely correlates with the energy metabolism, with its reduction potentially indicating the severity of injury.

Triacetonamine formation in a bio-oil from fast pyrolysis of sewage sludge using acetone as the absorption solvent.

A sewage sludge sample was pyrolyzed in a drop tube furnace at 500 degrees C and sweeping gas flow rate of 300cm(3)/min. Triacetonamine (TAA) was detected with GC/MS as major component in the resulting bio-oil using acetone as the absorption solvent and proven to be a product from the reaction of NH(3) in the bio-oil with the absorption solvent acetone. TAA yield increased with storage time and reached a level about 28.4% (% sludge fed, daf) after 175h. Since the reaction of pure NH(3) with acetone does not proceed, some species in the bio-oil must catalyze the reaction of NH(3) with acetone. TAA was isolated in a high yield (27.9%, daf) and high purity (80.4%) by column chromatography with different solvents, including mixed solvents, as eluants. The study revealed the possibility of sewage sludge as potential resource of TAA.

Conversion of the 2,2,6,6-tetramethylpiperidine moiety to a 2,2-dimethylpyrrolidine by cytochrome P450: evidence for a mechanism involving nitroxide radicals and heme iron.

Earlier we described a novel cytochrome P450 (CYP) catalyzed metabolism of the 2,2,6,6-tetramethylpiperidine (2,2,6,6-TMPi) moiety in human liver microsomes to a ring-contracted 2,2-dimethylpyrrolidine (2,2-DMPy) [Yin, W., et al. (2003) Drug Metab. Dispos. 31, 215-223]. In the current report, evidence is provided for the involvement of 2,2,6,6-TMPi hydroxylamines and their one-electron oxidation products, the nitroxide radicals, as intermediates in this pathway. Nitroxide radicals could be converted to their corresponding 2,2-DMPy metabolites by "inactivated CYP3A4", as well as by a number of other heme proteins and hemin, suggesting that this is a heme-catalyzed process. The conversion of nitroxide radicals to the 2,2-DMPy products by CYP3A4 or hemin was accompanied by the generation of acetone in incubations, providing evidence that the three-carbon unit from 2,2,6,6-TMPi was lost as acetone. With one model 2,2,6,6-TMPi nitroxide radical, evidence for an alternate pathway, which resulted in the formation of an intermediate that incorporated two oxygen atoms from water of the incubation medium before collapsing to the 2,2-DMPy product, was also obtained. To account for both pathways, a mechanism involving interaction of the nitroxide radicals with heme iron (Fe(III)), followed by a homolytic scission of the N-O bond and transfer of the nitroxide oxygen to heme iron to form a perferryl-oxygen complex, is proposed. The nitrogen-centered 2,2,6,6-TMPi radical thus formed then precipitates the contraction of the piperidine ring via C2-C3 bond cleavage, and the resulting product further oxidizes to an exocyclic iminium ion (by the perferryl-oxygen complex); the latter may undergo capture by water from the incubation medium and eliminate the three-carbon unit via N-dealkylation. It remains to be determined whether this novel interaction of nitroxide radicals with heme iron has any relevance in regard to the known biological properties of these stable radical species.

UVA-induced oxidative damage in retinal pigment epithelial cells after H2O2 or sparfloxacin exposure.

Retinal impairment is one of the leading causes of visual loss in an aging human population. To explore a possible cause for retinal damage in the human population, we have monitored DNA oxidation in human retinal pigment epithelial (RPE) cells after exposure to hydrogen peroxide (H2O2) or the quinolone antibacterial sparfloxacin. When H2O2- or sparfloxacin-exposed cells were further exposed to ultraviolet A (UVA) irradiation, oxidative damage to the DNA of these cells was greatly increased over baseline values. This RPE+pharmaceutical-UVA cell system was developed to mimic in vivo retinal degeneration, seen in mouse studies using quinolone and UVA exposure. DNA damage produced by sparfloxacin and UVA in RPE cells could be remedied by the use of antioxidants, indicating a possible in vivo method for prevention or minimization of retinal damage in humans

Involvement of singlet oxygen in cytochrome P450-dependent substrate oxidations.

Cytochrome P450 (P450)-dependent p-hydroxylation of aniline and o-deethylation of 7-ethoxycoumarin were examined in rat liver microsomes in the presence of radical scavengers. The addition of beta-carotene, a quencher of singlet oxygen species ((1)O(2)), suppressed the aniline hydroxylation, while the addition of sodium azide (NaN(3)) ((1)O(2) quencher) enhanced the reaction. No other reactive oxygen scavengers or chelating agents such as superoxide dismutase, catalase, dimethylsulfoxide, or deferoxamine altered the reaction. In contrast, the microsomal o-deethylation of 7-ethoxycoumarin was suppressed by the addition of NaN(3). (1)O(2) was detectable during the reaction of microsomes and NADPH by ESR spin-trapping when 2,2,6,6-tetramethyl-4-piperidone (TMPD) was used as a spin trap, and the (1)O(2) was quenched by the additions of beta-carotene, NaN(3), aniline, and 7-ethoxycoumarin. The enhancement effect of NaN(3) in the hydroxylation of aniline appeared to be due to the conformational change of P450 protein, which in turn enhances the binding of aniline to P450 in terms of the spectral dissociation constant (K(s)). In contrast, (1)O(2) appeared to be active in the o-deethylation of 7-ethoxycoumarin. On the basis of the results, the involvement of (1)O(2) in P450-dependent substrate oxygenations is proposed.

Irradiation of titanium dioxide generates both singlet oxygen and superoxide anion.

Although photoexcited TiO2 has been known to initiate various chemical reactions, such as the generation of reactive oxygen species, precise mechanism and chemical nature of the generated species remain to be elucidated. The present work demonstrates the generation of singlet oxygen by irradiated TiO2 in ethanol as measured by ESR spectroscopy using 2,2,6,6-tetramethyl-4-piperidone (4-oxo-TMP) as a 1O2-sensitive trapping agent. Under identical conditions, the superoxide ion was also detected by spin trapping agent 5,5-dimethyl-pyrroline-N-oxide (DMPO). Kinetic analysis in the presence of both 4-oxo-TMP and DMPO revealed that singlet oxygen is produced directly at the irradiated TiO2 surface but not by a successive reaction involving superoxide anion. The basis for this view is the fact that DMPO added in the mixture increased the signals responsible for 4-oxo-2,2,6,6-tetramethyl-1-piperidinyloxy (4-oxo-TEMPO), a reaction product of 4-oxo-TMP and 1O2. The detailed mechanism for the generation of 1O2 and superoxide ion by irradiated TiO2 and reactions between these species and DMPO are discussed.

Metabolism of the stable nitroxyl radical 4-oxo-2,2,6, 6-tetramethylpiperidine-N-oxyl (TEMPONE).

The formation of new metabolites of the stable nitroxyl radical 4-oxo-2,2,6,6-tetramethylpiperidine-N-oxyl (TEMPONE) inside the isolated perfused rat liver was examined. The paramagnetic 4-hydroxy derivative (TEMPOL) and the diamagnetic 1,4-dihydroxy derivative were found to be the major metabolites besides the well-known corresponding hydroxylamine of TEMPONE. No reoxidation of the hydroxyl group in the 4-position was observed. The conversion of nitroxides to the sterically hindered secondary amines remains speculative. A redox cycle of nitroxide and hydroxylamine including the secondary amines is discussed. For the first time the biotransformation of the stable nitroxyl radical TEMPONE detected by means of GC and GC-MS has been examined and new metabolites have been described, i.e. the newly discussed metabolites have to be considered for the interpretation of electron paramagnetic resonance (EPR), magnetic resonance imaging (MRI) and dynamic nuclear polarization (DNP) measurements on using the spin probe TEMPONE.

Bioreduction of Tempone and spin-labeled gentamicin by gram-negative bacteria: kinetics and effect of ultrasound.

The primary objective of this study is the investigation of bioreduction kinetics of hydrophilic spin probes, 2,2,6,6, -tetramethyl-4-oxo-piperidinyl-1-oxyl (Tempone), and spin-labeled antibiotic gentamicin by gram-negative bacteria maintained at various oxygen tensions, with emphasis on the effect of probe penetration rate. This information was used to evaluate the effect of ultrasound on the penetration of hydrophilic compounds, including antibiotics, into Pseudomonas aeruginosa and Escherichia coli cells. Penetration of spin-labeled compounds into the cells was assessed by the reduction rate of the nitroxyl moiety measured by EPR. In cell suspensions, both Tempone and spin-labeled gentamicin were localized predominantly in the aqueous phase surrounding the cells. However, a gradual reduction of the probes in contact with the cells indicated that the probes penetrated through the outer membrane and periplasmic space into the cytoplasmic membrane, where the electron transport chains and other metabolic activities of gram-negative bacteria are localized. The kinetics of probe reduction depended on oxygen tension and presence of electron transport chain blockers. It was found that probe penetration rate through the outer cell membrane affected the rate of probe reduction; damaging the permeability barrier by cell incubation with EDTA or by powerful insonation above the cavitation threshold increased the rate of probe reduction. In contrast, insonation below the cavitation threshold did not affect the rate of probe reduction. These findings imply that the recently observed synergistic effect between hydrophilic antibiotics and low frequency ultrasound in killing gram-negative bacteria did not result from the enhanced antibiotic penetration through bacterial cell walls.

Photosensitization with anticancer agents. 17. EPR studies of photodynamic action of hypericin: formation of semiquinone radical and activated oxygen species on illumination.

When hypericin was illuminated with 580 nm light in aqueous solution, the semiquinone radical, singlet oxygen, and superoxide anion radical were detected. The formation of the semiquinone radical and activated oxygen species and the transformation and competition between them depend on the quinone and oxygen concentrations, irradiation time and intensity, and the nature of substrate. In anaerobic solution containing a high concentration of the quinone, the semiquinone radical was predominantly photoproduced. In contrast, in aerobic solution, singlet oxygen is the principal product in the photosensitization of hypericin. Besides singlet oxygen, superoxide anion radical is generated by the quinone on illumination in aerobic solution via the reduction of oxygen by the semiquinone radical, but to a lesser extent than singlet oxygen. The generation of superoxide anion radical is significantly enhanced by the presence of electron donors.

The effect of oxygen at physiological levels on the detection of free radical intermediates by electron paramagnetic resonance.

It is well known that oxygen enhances the relaxation of free radical EPR probes through spin lattice and Heisenberg spin-spin interactions with consequent effect on the line height and width. The two relaxation processes have opposing effects on the signal heights and depend on the concentration of oxygen, the incident microwave power, and the presence of other paramagnetic species. During EPR studies of chemical, biochemical, and cellular processes involving free radicals, molecular oxygen has significant magnetic influence on the EPR signal intensity of the free radical species under investigation in addition to affecting the rates of production of the primary species and the stability of the spin adduct nitroxides. These effects are often overlooked and can cause artifacts and lead to erroneous interpretation. In the present study, the effects of oxygen and ferricyanide on the EPR signal height of stable and persistent spin adduct nitroxides at commonly employed microwave powers were examined. The results show that under commonly adopted EPR spectrometer instrumental conditions, artifactual changes in the EPR signal of spin adducts occur and the best way to avoid them is by keeping the oxygen level constant using a gas-permeable cell.

Free radical metabolites in myocardium during ischemia and reperfusion.

Low-temperature electron paramagnetic resonance (EPR) spectroscopy and spin traps were used to measure paramagnetic species generation in rat hearts and isolated mitochondria. The hearts were freeze-clamped at 77 K during control perfusion by the Langendorff procedure, after 20-30 min of normothermic ischemia or 10-30 s of reperfusion with oxygenated perfusate. All EPR spectra measured at 4.5-50 K exhibited signals of both mitochondrial free radical centers and FeS proteins. The analysis of spectral parameters measured at 243 K showed that free radicals in heart tissue were semiquinones of coenzyme Q10 and flavins. The appearance of a typical "doublet" signal at g = 1.99 in low-temperature spectra indicated that a part of ubisemiquinones formed a complex with a high potential FeS protein of succinate dehydrogenase. Ischemia decreased the free radical species in myocardium approximately 50%; the initiation of reflow of perfusate resulted in quick increase of the EPR signal. Mitochondria isolated from hearts during control perfusion and after 20-30 min of ischemia were able to produce superoxide radicals in both the NADH-coenzyme Q10 reductase and the bc1 segments of the respiratory chain. The rate of oxyradical generation was significantly higher in mitochondria isolated from ischemic heart.

Exchange and shuttling of electrons by nitroxide spin labels.

The ability of nitroxide spin labels to act as oxidizers of reduced nitroxides (hydroxylamines) in biological and model systems was demonstrated. All of the nitroxides tested were able to act as oxidizing agents with respect to hydroxylamine derivatives of nitroxides. The rates of these reactions were first order with respect to nitroxide concentration and with respect to hydroxylamine concentration, making the reaction second order overall. The second-order rate constants are reported for a number of these reactions. These reactions proceeded to an equilibrium state and the equilibrium constants for several combinations of reactants are presented. Both the rate constants and the equilibrium constants were found to be dependent on the ring structure of the nitroxide and hydroxylamine, with piperidines being reduced more easily and pyrrolidines and oxazolidines being oxidized more easily. All of the hydroxylamine derivatives were oxidized by air to their respective nitroxides, with the rate of this oxidation greater for pyrrolidines than for piperidines. Furthermore, hydroxylamines that are permeable to lipid bilayers were able to act as shuttles of reducing equivalents to liposome-encapsulated nitroxides that were otherwise inaccessible to reducing agents. This mechanism of shuttling of electrons was able to explain the relatively rapid reduction by cells of a nonpermeable nitroxide in the presence of a permeable nitroxide.

Oxidant stress in malaria as probed by stable nitroxide radicals in erythrocytes infected with Plasmodium berghei. The effects of primaquine and chloroquine.

Erythrocytes from normal mice and mice infected with the malarial parasite Plasmodium berghei reduce the water-soluble spin probes 2,2,6,6-tetramethylpiperidine-4-hydroxy-N-oxyl (TEMPOL), 2,2,6,6-tetramethylpiperidine-N-oxyl (TEMPO) and 2,2,6,6-tetramethylpiperidine-4-keto-N-oxyl (TEMPONE) at similar rates under both air and N2 atmospheres. The ESR signal of the lipid-soluble spin probe 5-doxyl-stearate is stable on incorporation into erythrocytes from normal mice. In contrast, parasitized red cells reduce this nitroxide probe, at a rate which increases with the level of parasitemia. Inhibitors of electron transport such as KCN and NaN3, increase the rate of reduction. We propose that nitroxide reduction occurs via the electron transport chain in the parasite. The antimalarial drug primaquine causes reduction of both water-soluble and lipid-soluble spin probes. This action of primaquine is independent of its ability to release H2O2 from oxyhemoglobin, and is ascribed to the ability of primaquine to accelerate flux through the hexose monophosphate shunt. The increased production of NADPH results in increased rates of reduction of the nitroxide radicals. Methylene blue, which also increases flux through the shunt, is even more effective than primaquine at reducing the nitroxides. Chloroquine has no such effect. Parasitized mice treated with chloroquine six hours prior to ESR measurements show less nitroxide reducing capacity than do untreated mice. Chloroquine is known to decrease flux through the hexose monophosphate shunt. The metabolic influences of the two antimalarial drugs are, thus, quite different.

Metabolic potentiation of the radiosensitization of hypoxic bacterial cells afforded by nitroaromatic compounds.

Prolonged preirradiation incubation of nitroaromatic radiosensitizers with Escherichia coli cells has been found to increase the degree of radiosensitization of the cells in anoxia. Studies with E. coli strains which differ in their nitroreductase activity indicate that the increase in sensitization arises from the action of metabolites produced by the nitroreductase system of the cell. The metabolites alone appear to decrease the extrapolation number of irradiated hypoxic cells and when combined with the parent compound give a biphasic survival curve. The combination of misonidazole (1 mmole dm-3) and its metabolites (1 mmole dm-3) gave initial and final enhancement ratios of 2.4 and 1.4, respectively. The final enhancement ratio is that expected for 1 mmole dm-3 misonidazole alone, whereas the initial enhancement ratio indicates that the metabolites potentiate the action of misonidazole. The preirradiation incubation effect is removed by dithiothreitol at concentrations which do not affect the radiosensitization level of the nitroaromatic sensitizer. This result indicates that the active metabolite probably depletes a certain amount of the free-thiol compounds inside the cell which assist in the repair of radiation-induced damage.

Effect of glutamic and aspartic acids on adenine nucleotides, nitrogenous compounds and contractile function during underperfusion of isolated rat heart.

The experiments were carried out to find out whether exogenous glutamic or aspartic acid could diminish changes in the cardiac contractile function and high-energy phosphate content caused by underperfusion of isolated isovolumic rat heart. After 40 min of reduced coronary flow (from 10 to 3 ml/min) there was an almost four-fold fall in the developed pressure, and more than three-fold rise in the diastolic pressure as well as a profound fall in creatine phosphate (CP) and ATP content. Glutamic (68 mM) or aspartic (75 mM) acids were added to the perfusate after 10 min of underperfusion when the developed pressure had declined almost to the same level as was observed after 40 min and the content of CP was reduced more than two-fold. Glutamic acid completely prevented the rise in the diastolic pressure and significantly increased the CP content, as compared to its level observed before addition of glutamate, but glutamic acid did not change the developed pressure. As a result, the CP and ATP contents were three- and two-fold higher, respectively, after addition of glutamic acid as compared to control underperfused hearts. Similar, but slightly less prominent effects were observed when aspartic acid was added instead of glutamic acid. These results suggest that high concentrations of glutamic and aspartic acids can exert beneficial effects on ischemic heart muscle.

Distribution of 2,2,6,6-tetramethyl-4-oxopiperidine-1-oxyl free radical in normal and neoplastic animal tissues.

The free radical 2,2,6,6-tetramethyl-4-oxopiperidine-1-oxyl (TMPO) was injected i.p. in doses of 100 mg/kg bw into Syrian hamsters: untreated, partially hepatectomized and grafted with transplantable tumours as well as into mice with B16 melanotic melanoma or with an adenocarcinoma. One hour after application of the compound its content was determined spectrometrically in livers, kidneys, lungs and all tumours. The characteristic triplet signal of TMPO was registered in the hamster and mouse melanotic melanomas but not in all other animal tissues and tumours. This may be the result of an enzyme defect in the melanotic melanoma cells or of a retention of TMPO by melanin. It was also found that TMPO is metabolized predominantly in the livers of the animals.

Binding of a nitroxyl to radiation-induced DNA transients in repair and repair deficient of E. coli K-12.

Binding of tritiated 2,2,6,6-tetramethyl-4-piperidone-N-oxyl (3H-TAN) to radiation-induced DNA-transients in E. coli K-12 strains AB 1157 and JO 307 rec A uvr A has been studied under in vivo conditions. After irradiation the cells were washed and resuspended in growth medium and left overnight at 37 degrees C. Within an uncertainty of about 10%, no effect of repair could be detected on the yield of TAN bound to DNA for any of the strains. During the period after resuspension. TAN or fragments of TAN leaked out of the irradiated cell samples. This leakage may be attributed to semi-permanant association between TAN and radiation-induced radicals within the cell. The relevance of different interactions between TAN and transients in DNA is discussed.