Oxidation of glutathione and reduced pyridine nucleotides by the myotoxic and mutagenic aromatic amine, 1,2,4-triaminobenzene

Toxicity of para-phenylenediamine (PPD;1, 4 diaminobenzene) on isolated human lymphocytes: The key role of intracellular calcium enhancement in PPD-induced apoptosis

Para-phenylenediamine (PPD) is a derivative of benzene used as an ingredient in dyes, a photographic developing agent, and a component of engineered polymers. The carcinogenicity of PPD, which has been documented in several studies, may be related to its toxic effects on different compartments of the immune system. The main goal of this research was to evaluate the mechanism of the toxicity of PPD on human lymphocytes by exploiting the accelerated cytotoxicity mechanism screening (ACMS) technique. Lymphocytes were isolated from the blood of healthy persons using a Ficoll-Paque PLUS standard method. Assessment of cell viability was carried out 12 h following treatment of human lymphocytes with 0.25-1 mM PPD. For determination of cellular parameters, isolated human lymphocytes were incubated with 1/2 the IC50 (0.4 mM), the IC50 (0.8 mM), and twice the IC50 (1.6 mM) for 2, 4, and 6 h. Half maximal inhibitory concentration (IC50) is the concentration that reduces cell viability approximately 50% following treatment. The results of this study demonstrated that PPD-associated apoptosis in human lymphocytes was mainly through the enhancement of intracellular calcium, oxidative stress, and following adverse effect on lymphocyte organelles (like mitochondria and lysosomes). Lipid peroxidation, activation of caspase-3, and stimulation of cytokines (IL₂, interferon-gamma (IFN-γ), and TNF-alpha) production were also observed in PPD-treated lymphocytes. Considering the results of this study, we can suggest an association between PPD carcinogenicity and its toxic effects on different compartments of the immune system.

Percutaneous penetration and metabolism of 2-nitro-p-phenylenediamine in human and fuzzy rat skin

2-Nitro-p-phenylenediamine (2NPPD) is a dye used in semipermanent and permanent (tinting color) hair dye formulations. National Toxicology Program toxicology and carcinogenesis testing of 2NPPD has raised concerns about its safety. Therefore, we initiated in vitro studies to measure absorption and metabolism of 2NPPD in human and fuzzy rat skin and rat jejunal tissue. Intestinal tissue metabolism of 2NPPD was compared to skin metabolism since toxicology data from oral 2NPPD studies will be used for future safety assessment purposes. Absorption was measured over 24 h by using flow-through diffusion cells with a receptor fluid consisting of Hepes-buffered Hank's balanced salt solution. Dosing vehicles were applied to skin and intestine in the diffusion cells for 30 min. 2NPPD metabolites were determined by high-performance liquid chromatography methodology. In human skin, the percentages of total applied dose absorbed (receptor fluid + skin) over 24 h were 9.2 +/- 5.7 (mean +/- SD) and 9.5 +/- 3.2 for the ethanol and semipermanent vehicles, respectively, with approximately 3% remaining in skin. In rat skin, the percentages of total applied dose absorbed over 24 h were 9.3 +/- 1.2 (mean +/- SE), 6.9 +/- 1.2, and 4.2 +/- 0.1 for the ethanol, semipermanent, and permanent formulation vehicles, respectively, with approximately 3% remaining in skin. In rat intestinal tissue, the percentage of total applied dose absorbed over 24 h was 10.9 +/- 1.2, with approximately 5% remaining in the tissue. In human and rat skin, 2NPPD was metabolized to triaminobenzene and N4-acetyl-2NPPD. 2NPPD was also metabolized to a sulfated 2NPPD metabolite in rat skin, but not in human skin. 2NPPD was extensively metabolized in both human and rat skin with ethanol application; metabolism was not as extensive with a semipermanent formulation application. In rat intestinal tissue, 62% of 2NPPD was metabolized upon absorption to triaminobenzene and N4-acetyl-2NPPD. Differences in the metabolic profiles (proportion of each metabolite formed) were found between the skin and intestinal tissue. These results suggest that 2NPPD is rapidly absorbed and extensively metabolized in both skin and intestinal tissue. The extent of metabolism and the metabolic profile were found to be species-, tissue-, and dosing vehicle-dependent. Metabolism information will be useful in predicting the extent of 2NPPD and/or 2NPPD metabolite systemic absorption relative to a dermal exposure, which will improve the health hazard assessment of 2NPPD.

Generation of superoxide radical and hydrogen peroxide by 2,3,6-triaminopyridine, a metabolite of the urinary tract analgesic phenazopyridine

2,3,6-Triaminopyridine, a metabolite of the widely-used drug phenazopyridine, has been shown to autoxidize at neutral pH, generating superoxide radical and hydrogen peroxide. Hydrogen peroxide was also detected in erythrocytes exposed to this substance, and these cells suffered oxidative damage, as reflected by methaemoglobin formation and glutathione depletion. The in vitro effects of 2,3,6-triaminopyridine are closely similar to those of the structurally-related compound, 1,2,4-triaminobenzene. The latter substance is known to be highly toxic in vivo by mechanisms which may involve free radical production and oxidative stress. It is possible, therefore, that triaminopyridine may be similarly toxic in animals and that this metabolite could be responsible for some of the harmful side-effects associated with phenazopyridine use.

Mitochondrial oxidation of p-phenylenediamine derivatives in vitro: structure-activity relationships and correlation with myotoxic activity in vivo

A number of p-phenylenediamine derivatives are known to cause necrosis of skeletal and/or cardiac muscle when administered to experimental animals. Compounds of this type are oxidized to semiquinonedi-imines or quinonedi-imines by mitochondria in vitro, establishing alternative pathways for electron transport in the respiratory chain with concomitant decreases in respiratory control and ADP:O ratios. Muscle mitochondria were found to be particularly effective in promoting p-phenylenediamine oxidation in vitro and the magnitude of the mitochondrial effects of the various compounds tested correlated well with their ability to cause muscle necrosis in vivo. It is suggested that mitochondrial oxidation may be involved in the initiation of the myotoxic effects of these compounds and account for their target-site specificity.

Reactions of the Wurster's blue radical cation with thiols, and some properties of the reaction products

Formation of 1-electron oxidation products of aromatic amines in biological systems have been ascertained. The mechanisms of the toxic actions of the aminyl radicals and their corresponding detoxication reactions are much less established. During the studies of reactions of GSH with the N,N,N',N'-tetramethyl-p-phenylenediamine radical cation (TMPD) (Wurster's blue) two pathways were detected: (1) a slow second order reaction (k = 5 M-1.s-1) which gave the parent amine and (ultimately) GSSG, and (2) a fast, complex reaction which yielded 2-(glutathione-S-yl)-N,N,N',N'-tetramethyl-p-phenylenediamine (2-GS-TMPD). From kinetic reasons, this reaction was suggested to be composed of a rapid disproportionation reaction followed by a reductive 1,4-Michael-addition. This reaction pathway prevailed at GSH concentrations below 1 mM. At higher GSH concentrations formation of the thioether was suppressed. This hypothesis was confirmed when the reaction of the highly labile N,N,N',N'-tetramethyl-p-quinonediiminium dication (TMQDI++) with GSH was followed: In this case, thioether formation outweighed clearly reductive mechanisms, the latter yielding ultimately the amine and GSSG. Similar to N,N,N',N'-tetramethyl-p-phenylenediamine (TMPD), 2-GS-TMPD was also capable of producing ferrihemoglobin in a catalytic reaction. Its rate, however, was only 3% that observed with the parent amine. During this reaction the thioether was apparently oxidized to the corresponding quinonediiminium dication, which gave the corresponding quinonemonoimine on acidification.

Concerted action of reduced glutathione and superoxide dismutase in preventing redox cycling of dihydroxypyrimidines, and their role in antioxidant defence

Dialuric Acid, the reduced form of the beta-cell toxin alloxan, and the related fava bean derivatives divicine and isouramil, autoxidize rapidly in neutral solution by a radical mechanism. GSH promotes redox cycling of each compound, with concomitant GSH oxidation and H2O2 production. With superoxide dismutase present, there is a lag period in which little oxidation occurs, followed by rapid oxidation. GSH extends this lag and decreases the subsequent rate of oxidation, so that with superoxide dismutase and a sufficient excess of GSH, coupled oxidation of GSH and each pyrimidine is almost completely suppressed. This mechanism may be a means whereby GSH in combination with superoxide dismutase protects against the cytotoxic effects of these reactive pyrimidines. Superoxide dismutase may also protect cells against oxidative stress in other situations where GSH acts as a radical scavenger, and we propose that the concerted action of GSH and superoxide dismutase constitutes an important antioxidant defence.

Structure-activity relationships in the myotoxicity of ring-methylated p-phenylenediamines in rats and correlation with autoxidation rates in vitro

A number of N-methylated p-phenylenediamines are known to cause necrosis of skeletal and cardiac muscle in rats. The severity of the muscle damage induced by these compounds in vivo was found to be directly proportional to their autoxidation rates in vitro, suggesting that reactive species formed during oxidation may be involved in the initiation of this toxic effect. In the present study, the in vitro oxidation rates and in vivo toxicities of a number of ring-methylated p-phenylenediamines have been evaluated. 2,3,5,6-Tetramethyl p-phenylenediamine readily autoxidized at neutral pH. Hydrogen peroxide was formed in this reaction, while oxidation in the presence of glutathione or reduced pyridine nucleotides led to the production of both hydrogen peroxide and superoxide radical. Less highly methylated derivatives oxidized more slowly, with rates decreasing in the order 2,3,5,6-tetramethyl greater than 2,5-dimethyl greater than 2,6-dimethyl greater than 2-methyl. All these compounds were myotoxic in rats, with damage being largely confined to skeletal muscle. Toxicity was again proportional to oxidation rate. Myotoxicity appears to be a general property of certain substituted p-phenylenediamines and the structure-activity relationships identified may permit an estimate to be made of the potential toxicity of other compounds of this type.

Inhibition of autoxidation of divicine and isouramil by the combination of superoxide dismutase and reduced glutathione

The effects of GSH on the autoxidation of the fava bean pyrimidine aglycones, divicine and isouramil, and on acid-hydrolyzed vicine (provisional identification 2-amino-4,5,6-trihydroxypyrimidine) have been studied. GSH alone promoted redox cycling of each compound, with concomitant GSH oxidation and H2O2 production. In the presence of superoxide dismutase, there is a lag period during which little pyrimidine oxidation occurs, followed by a period of accelerated oxidation. With the three pyrimidines, increasing concentrations of GSH extended this lag period and progressively decreased subsequent rates of both pyrimidine oxidation and O2 uptake. No GSH oxidation or O2 uptake occurred during the lag. These results show that the combination of GSH and superoxide dismutase is able to inhibit redox cycling of the pyrimidines. With a 10-fold excess of GSH over isouramil or acid-hydrolyzed vicine (20-fold with divicine) this coupled oxidation of GSH and the pyrimidine is almost completely suppressed. This mechanism may be a means whereby GSH in combination with superoxide dismutase protects against the cytotoxic effects of these reactive pyrimidines.

Generation of superoxide radical, hydrogen peroxide and hydroxyl radical during the autoxidation of N,N,N',N'-tetramethyl-p-phenylenediamine

The autoxidation of N,N,N',N'-tetramethyl-p-phenylenediamine (TMPD) at neutral pH has been shown to generate superoxide radical and hydrogen peroxide. The rate of formation of these species was increased in the presence of certain iron and copper compounds; in the presence of iron complexed with EDTA, hydroxyl radical was also produced. Hydrogen peroxide was detected in erythrocytes incubated with TMPD and these cells suffered oxidative damage as reflected by methaemoglobin formation and glutathione depletion; the one-electron oxidation product of TMPD, Wurster's Blue, was equally effective in producing such changes in erythrocytes. N-Methylated p-phenylenediamines are known to be mutagenic and myotoxic, and it is suggested that 'active oxygen' species may be involved in the initiation of these harmful effects.