Skin-tumour promoting activity of methyl ethyl ketone peroxide—a potent lipid-peroxidizing agent

Iron overload augments 7,12-dimethylbenz(a)anthracene-initiated and 12-O-tetradecanoylphorbol-13-acetate-promoted skin tumorigenesis

Reactive oxygen species and free radicals have been implicated in the multistep cutaneous chemical carcinogenesis. Much of the experimental evidence in this regard is indirect and is based on observations that prooxidant status usually enhances and antioxidant treatments generally inhibit tumor yield. Iron overload is known to enhance peroxidative damage and cause oxidative stress. In this study, we report that iron overload augments 12-O-tetradecanoylphorbol-13-acetate (TPA)-mediated cutaneous tumor promotion. Female Swiss mice were subjected to iron overload by injecting 1 mg iron/ mouse/day consecutively for 2 weeks. Tumors were initiated by applying a single dose of 7,12-dimethylbenz(a)anthracene and promoted with twice weekly applications of TPA for 20 weeks and the appearance of first tumor (latency period), percent incidence and number of tumors per mouse were recorded. It has been observed that the level of iron in involved (tumor-bearing) skin was about fourfold higher as compared to uninvolved (non-tumor) skin of iron overload animals and about tenfold higher as compared to the iron level in the skin of normal animals. When compared to the iron-unloaded control group, the iron overload mice showed an increased incidence of tumors. In iron overload animals, the tumors appeared 3 weeks earlier and also the number of tumors per mouse was significantly higher (2.5-fold). These data indicate that iron overload augments TPA-mediated tumor promotion. We propose that oxidative stress generated by iron overload may be responsible for the augmentation of cutaneous tumorigenesis.

Activities of superoxide dismutase and glutathione peroxidase enzymes in cancerous and non-cancerous human kidney tissues

The activities of superoxide dismutases (total, cytoplasmic and mitochondrial) and glutathione peroxidase were measured in 10 cancerous and 10 non-cancerous adjacent human kidney tissues. Total (T-SOD) and cytoplasmic (Cu, Zn-SOD) superoxide dismutase and glutathione peroxidase (GSH-Px) activities were found lower in cancerous tissues compared with those of non-cancerous ones. However, no difference was found between the mitochondrial (Mn-SOD) superoxide dismutase activities of the tissues. Similarly, no differences were observed between the enzyme activity values of the tissues at stage I-II and III-IV renal cancer. In correlation analysis the positive relation found between Cu, Zn-SOD and GSH-Px enzymes in the non-cancerous tissues was found to be absent in the cancerous ones. The results suggest that enzymatic free radical defense mechanism is significantly reduced in the cancerous human kidney tissues due to depressed Cu, Zn-SOD and GSH-Px activities.

Impaired enzymatic antioxidant defense mechanism in cancerous human thyroid tissues

The activities of total superoxide dismutase (SOD), glutathione peroxidase (GSH-Px) and catalase (CAT) enzymes were measured in cancerous and non-cancerous adjacent tissues from 15 patients with follicular thyroid cancer containing single nodule. SOD and GSH-Px activities were found lower but malondialdehyde levels higher in cancerous tissues compared with those of noncancerous ones. However, no difference was found between CAT activities of the tissues. Activity decrease of GSH-Px enzyme in cancerous tissue was greater than that of SOD enzyme. Results suggested that enzymatic free radical defense system was significantly impaired and lipid peroxidation increased in the cancerous human thyroid tissues.

Radical production from peroxide and peracid tumour promoters: EPR spin trapping studies

EPR spin trapping using the spin traps 5,5-dimethyl-1-pyrroline N-oxide (DMPO) and 3,5-dibromo-4-nitrosobenzene sulphonic acid (DBNBS) has been employed to examine the generation of radicals from a number of organic peroxides and peracids which are known or suspected tumour promoters. All of the compounds when incubated with rat liver microsomal fractions in the presence of NADPH or NADH are metabolised to radical species which can be detected, and in most cases identified definitively, as the corresponding spin adducts; the assignment of particular signals to certain spin adducts has been confirmed by photolytic experiments. In the majority of cases, the predominant species are the arenecarbonyloxyl [RC(O)O.] and hydroxyl radical adducts. The mechanism of formation of the former species is shown to be enzymatic and cytochrome P-450 dependent and requires the presence of reducing equivalents. This type of radical is shown to undergo ready decarboxylation to give aryl radicals in agreement with previous chemical studies. The detection of these radical species, which are known to cause DNA strand breaks and be cytotoxic, with all the compounds tested, provides strong supportive evidence for the theory that it is the generation of radical species from these compounds which is the cause of their tumour-promoting activity.

In vivo thiyl free radical formation from hemoglobin following administration of hydroperoxides

Although free radical formation due to the reaction between red blood cells and organic hydroperoxides in vitro has been well documented, the analogous in vivo ESR spectroscopic evidence for free radical formation has yet to be reported. We successfully employed ESR to detect the formation of the 5,5-dimethyl-1-pyrroline-N-oxide (DMPO)/hemoglobin thiyl free radical adduct in the blood of rats dosed with DMPO and tert-butyl hydroperoxide, cumene hydroperoxide, ethyl hydrogen peroxide, 2-butanone hydroperoxide, 15(S)-hydroperoxy-5,8,11,13-eicosatetraenoic acid, or hydrogen peroxide. We found that pretreating the rats with either buthionine sulfoximine or diethylmaleate prior to dosing with tert-butyl hydroperoxide decreased the concentration of nonprotein thiols within the red blood cells and significantly enhanced the DMPO/hemoglobin thiyl radical adduct concentration. Finally, we found that pretreating rats with the glutathione reductase inhibitor 1,3-bis(2-chloroethyl)-1-nitrosourea prior to dosing with tert-butyl hydroperoxide enhanced the DMPO/hemoglobin thiyl radical adduct concentration and induced the greatest decrease in nonprotein thiol concentration within the red blood cells.

Radical production in liver mitochondria by peroxidic tumor promoters

Eleven peroxides have been tested to determine if there is a correlation between tumor-promoting activity and the ability to stimulate radical production in mitochondria. When non-respiring rat liver mitochondria are treated with these peroxidic compounds in the presence of DMPO, ESR signals are observed from the spin trapping of carbon- and oxygen-centered radicals in the case of 4 of the 7 peroxides that are known to be tumor promoters. Enhancement of carbon-centered radical production is observed in the presence of respiratory substrate. Thus there does not appear to be a correlation between tumor-promoting activity of peroxidic compounds and radical production in mitochondria. Oxidants can act as promoters either by 1- or 2-electron oxidation pathways; both types of mechanisms may be inhibited by antioxidants, which can scavenge either radicals or electrophiles.

Antioxidants--carcinogenic and chemopreventive properties

Synthetic and naturally occurring antioxidants have a wide variety of biological actions in rodents in addition to their primary antioxidant activity. Some of the included biological effects are of direct interest in relation to studies of carcinogenicity and/or modulation of carcinogenesis. Since the synthetic antioxidant BHA was first found to exert carcinogenic potential in rat and hamster forestomach epithelium, many other synthetic and naturally occurring antioxidants have been examined for their ability to induce proliferative activity in the alimentary canal. These studies have revealed that caffeic acid and sesamol are also tumorigenic for rat forestomach epithelium, whereas catechol and p-methylcatechol induce neoplasia in rat glandular stomach epithelium. Although the proliferative response is very rapid, with inflammation and ulceration, it takes a very long time before carcinomas develop. The proliferative lesions in the forestomach induced by BHA or caffeic acid are largely reversible, in contrast to those induced by genotoxic carcinogens, which generally persist and develop into cancer. Therefore, chronic irritation is considered to be responsible for the induction of stomach cancer by antioxidants. Butylated hydroxyanisole can undergo oxidative metabolism in vitro, and some of the metabolites formed have the potential for binding to proteins. Neither BHA nor its metabolites binds to DNA in vivo, but protein binding in the forestomach was greater than 10 times higher than that in the glandular stomach. It is thus conceivable that BHA is oxidatively metabolized in the forestomach epithelium (possibly entering into redox cycling), and reactive metabolites including semiquinone radicals or active oxygen species are responsible for the carcinogenesis by a mechanism involving binding to macromolecules. Many antioxidants have been shown to modify carcinogenesis, and as a rule, they inhibit the initiation stage by reducing the interaction between carcinogen and DNA. However, both promotion and inhibition have been reported for second-stage carcinogenesis, depending on the organ site, species of animal, or initiating carcinogen. They can also block reaction of amine and nitrite to form nitrosamines or reduce TPA promotion of skin carcinogenesis. Generally high doses of antioxidants are required for carcinoma induction or modification of chemical carcinogenesis. The significance of the reported tumorigenicity and strong promoting activity of antioxidants for forestomach epithelium of animals to the development of human cancer appears limited mainly because humans do not have a forestomach. The carcinogenic and strong promoting activities of catechol and its structurally related compounds on rat glandular stomach epithelium are of greater concern because this tissue is directly analogous to human gastric epithelium.(ABSTRACT TRUNCATED AT 400 WORDS)

Antioxidants and multistage carcinogenesis in mouse skin

The two-step initiation-promotion protocol for the induction of skin tumors in mice is a convenient model to elucidate what molecular events are involved in the multistage process of carcinogenesis and how they can be modulated. The current theories concerning the mechanisms of skin tumor initiation, stages 1 and 2 of tumor promotion, and tumor progression are reviewed. Because chemical carcinogens and tumor promoters may, directly or indirectly, generate reactive oxygen species (ROS) and because various antioxidants inhibit effectively some of the biochemical and biological events linked to tumor initiation, promotion and/or progression, it is conceivable that different sequences and levels of free radical-induced macromolecule damage may contribute to the evolution of the epidermal target cells from the preneoplastic stage to the malignant stage.

Stimulation of hydroperoxide generation in mouse skins treated with tumor-promoting or carcinogenic agents in vivo and in vitro

The levels of hydroperoxides in mouse skin (epidermis + dermis) homogenates incubated in the presence and absence of enzymic and non-enzymic generators of reactive oxygen species are rapidly increased by 12-O-tetradecanoylphorbol-13-acetate (TPA). Moreover, the homogenates prepared from skins treated repeatedly with TPA or 7,12-dimethylbenz[a]anthracene (DMBA) in vivo contain substantially more hydroperoxides, and accumulate more hydroperoxides in the presence of NaN3 and NADPH, than their counterparts prepared from control skins receiving acetone only. Various agents increase the levels of hydroperoxides in skin homogenates in relation with their tumor-promoting or carcinogen activities, suggesting that an increased level of peroxidation may be involved in the multistage process of skin carcinogenesis.

Antioxidant prevention of tumor promoter induced inhibition of mouse hepatocyte intercellular communication

The liver tumor promoters, phenobarbital (20-500 micrograms/ml), lindane (1,2,3,4,5,6-hexachlorocyclohexane, gamma-isomer; 0.1-5.0 micrograms/ml), and DDT (1,1-bis[4-chlorophenyl]-2,2,2-trichloroethane; 0.5-10.0 micrograms/ml), and the hydrogen peroxide-generating enzyme, glucose oxidase (0.01-0.10 units/ml) inhibited gap junctional intercellular communication between B6C3F1 mouse hepatocytes in primary culture. Addition of the antioxidants, superoxide dismutase (100 units/ml), DPPD (N,N'-diphenyl-1,4-phenylenediamine; 25 microM), and vitamin E (DL-alpha-tocopherol acetate; 100 microM), to tumor promoter-treated cultures prevented the inhibition of hepatocyte intercellular communication. DPPD and vitamin E, prevented the inhibition of hepatocyte intercellular communication by glucose oxidase. Superoxide dismutase had no effect on the inhibition of intercellular communication caused by glucose oxidase. These results suggest that activated oxygen species are produced during liver tumor promoter treatment of cultured mouse hepatocytes and are responsible for the inhibition of mouse hepatocyte intercellular communication by the promoters.

Inhibition of glutathione S-transferase P type-positive foci development by linolic acid hydroperoxides and their secondary oxidative products in a rat in vivo mid-term test for liver carcinogens

The effects of linolic acid hydroperoxides (product A) and secondary oxidative products of product A (product B), were examined in an in vivo mid-term test for hepatocarcinogens or hepatopromoters in rats. The number of placental type of glutathione S-transferase (GST-P)-positive foci of the liver was significantly reduced in rats given diethylnitrosamine (DEN) followed by products A (4.64 +/- 1.09, P less than 0.05) or B (3.62 +/- 1.65, P less than 0.01) as compared to the controls given carcinogen alone (6.31 +/- 2.82). The area of GST-P positive foci was also significantly reduced in rats given DEN followed by product B (0.30 +/- 0.21, P less than 0.05) as compared to the controls (0.47 +/- 0.23). These results suggest that linolic acid hydroperoxides or their secondary oxidative products are not hepatocarcinogens and rather may possess inhibitory potential for liver carcinogenesis.