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

Modeling skin sensitization potential of mechanistically hard-to-be-classified aniline and phenol compounds with quantum mechanistic properties

Background

Advanced structure-activity relationship (SAR) modeling can be used as an alternative tool for identification of skin sensitizers and in improvement of the medical diagnosis and more effective practical measures to reduce the causative chemical exposures. It can also circumvent ethical concern of using animals in toxicological tests, and reduce time and cost. Compounds with aniline or phenol moieties represent two large classes of frequently skin sensitizing chemicals but exhibiting very variable, and difficult to predict, potency. The mechanisms of action are not well-understood.

Methods

A group of mechanistically hard-to-be-classified aniline and phenol chemicals were collected. An in silico model was established by statistical analysis of quantum descriptors for the determination of the relationship between their chemical structures and skin sensitization potential. The sensitization mechanisms were investigated based on the features of the established model. Then the model was utilized to analyze a subset of FDA approved drugs containing aniline and/or phenol groups for prediction of their skin sensitization potential.

Results and discussion

A linear discriminant model using the energy of the highest occupied molecular orbital (ϵ_HOMO) as the descriptor yielded high prediction accuracy. The contribution of ϵ_HOMO as a major determinant may suggest that autoxidation or free radical binding could be involved. The model was further applied to predict allergic potential of a subset of FDA approved drugs containing aniline and/or phenol moiety. The predictions imply that similar mechanisms (autoxidation or free radical binding) may also play a role in the skin sensitization caused by these drugs.

Conclusions

An accurate and simple quantum mechanistic model has been developed to predict the skin sensitization potential of mechanistically hard-to-be-classified aniline and phenol chemicals. The model could be useful for the skin sensitization potential predictions of a subset of FDA approved drugs.

Electronic supplementary material

The online version of this article (doi:10.1186/2050-6511-15-76) contains supplementary material, which is available to authorized users.

Phenylenediamine induced hepatocyte cytotoxicity redox. Cycling mediated oxidative stress without oxygen activation

Muscle necrosis induced by various phenylenediamine derivatives has been correlated with their autoxidation rate. However, a more detailed investigation of the cytotoxic mechanism using a model system of isolated hepatocytes and 2,3,5,6-tetramethylphenylenediamine (DD) shows little oxygen activation as indicated by the absence of cyanide resistant respiration, lipid peroxidation and lack of cytoprotection by iron chelators, superoxide dismutase mimics and xanthine oxidase inhibitors. Cytotoxicity was however attributed to oxidative stress as GSH was not only rapidly oxidized to GSSG but mixed protein disulfide formation also occurred. Furthermore, the disulfide reductant dithiothreitol added some time after DD restored protein thiols and prevented further cytotoxicity. This oxidative stress was attributed to a futile two electron redox cycle involving oxidation of DD to the corresponding diimine by the mitochondrial electron transport chain and rereduction by DT diaphorase. Evidence suggesting this was that both diimine accumulation and the ensuing cytotoxicity were markedly increased by inactivating hepatocyte DT diaphorase but were prevented by a subtoxic concentration of the mitochondrial respiratory inhibitor cyanide. Furthermore, addition of NADH generating substrates such as lactate, sorbitol, xylitol or ethanol prevented DD induced GSH oxidation and cytotoxicity. This suggests that DD undergoes intracellular redox cycling without oxygen activation until the hepatocyte is unable to maintain redox homeostasis and mixed protein disulfide cytotoxicity ensues.

Reactions of the Wurster's red radical cation with hemoglobin and glutathione during the cooxidation of N,N-dimethyl-p-phenylenediamine [correction of phenlenediamine] and oxyhemoglobin in human red cells

N,N-Dimethyl-p-phenylenediamine (DMPD) reacted directly with oxyhemoglobin under formation of ferrihemoglobin and, presumably, the N,N-dimethyl-p-phenylenediamine radical cation (DMPP.+). The apparent second-order rate constant of this reaction was 1 M-1 s-1 (pH 7.4, 37 degrees C). The reaction rate was diminished by catalase (by 1/3) and by superoxide dismutase (by 1/5). The apparent second-order rate constant of ferrihemoglobin formation by DMPD.+ was 5 x 10(3) M-1 s-1. Since DMPD.+ is disproportionated by 50% at pH 7.4, the quinonediimine could not be excluded as the ultimate ferrihemoglobin forming oxidant. To prove this hypothesis, the disproportionation equilibrium was shifted to the radical side by addition of excess DMPD. Ferrihemoglobin formation was thereby increased, indication that the radical was the responsible oxidant. In contrast to ferrihemoglobin formation, reactions with glutathione occurred predominantly with the quinonediimine. The second-order rate constant of this reaction was 4 x 10(5) M-1 s-1 which approaches the value obtained with p-benzoquinone. In contrast to the corresponding reactions of the N,N,N',N'-tetramethyl-p-phenylenediamine radical cation, the disporportionation reaction of DMPD.+ was very fast, k = 2 x 10(6) M-1 s-1. Formation of glutathione disulfide was negligible and the main reaction products were two isomeric glutathione adducts, 2- and 3-(glutathione-S-yl)-N,N-dimethyl-p-phenylenediamine. In human erythrocytes, DMPD produced many equivalents of ferrihemoglobin, diminished glutathione and produced both thioethers. In contrast to ferrihemoglobin formation, DMPD and glutathione disappearance as well as thioether appearance occured only after a marked lag phase. The calculated steady state concentration of DMPD.+ was only 4 x 10(-6) the DMPD concentration, as long as ferrihemoglobin was low. At increasing ferrihemoglobin higher steady state concentrations of the radical are attained. In fact, preformed ferrihemoglobin in red cells significantly accelerated DMPD and glutathione disappearance. This effect was completely prevented in the presence of ferrihemoglobin-complexing cyanide. The presented experiments once more appoint blood as a metabolically competent organ for the biotransformation of aromatic amines.

Quantitative determination by ESR of the arylaminyl free radical during the reaction of N,N,N',N'-tetramethyl-p-phenylenediamine with oxyhemoglobin

Aromatic amines with electron-donating substituents are directly activated by pure oxyhemoglobin with formation of ferrihemoglobin. Of these xenobiotics the N-alkylated p-phenylenediamines are particularly active. With N,N,N',N'-tetramethyl-p-phenylenediamine (TMPD) cooxidation with oxyhemoglobin was observed by ESR spectroscopy with formation of the arylaminyl free radical (TMPD+*). Since the radical is rapidly reduced by ferrohemoglobin, a catalytic cycle of ferrihemoglobin formation is sustained with initially very low steady-state concentrations of the radical, e.g. below 0.1%. Ferrihemoglobin is also able to oxidize TMPD to the radical, hence the steady-state concentration of TMPD+* rises with increasing ferrihemoglobin. Radicals of the Wurster's type tend to disproportionate at high rates generating reactive quinonediiminium cations which oxidize and arylate cellular thiols like GSH and protein SH groups. Because the disproportionation rate depends on the square of the radical concentration, quenching of the radicals by ferrohemoglobin to protect cellular thiols will be effective as long as the capacity of the methemoglobin reductase system is not overwhelmed. The results indicate that erythrocytes may play a critical role in activation and detoxication of p-phenylenediamines.