The group of perylene quinone-type Alternaria toxins contains several congeners with epoxide groups, for example, altertoxin II (ATX II) and stemphyltoxin III (STTX III). Recent studies in our laboratory have disclosed that the epoxide moieties of ATX II and STTX III are reduced to alcohols in human colon Caco-2 cells, thereby resulting in the formation of altertoxin I (ATX I) and alteichin, respectively. In the present study, this pathway was demonstrated for ATX II in three other mammalian cell lines. Furthermore, the chemical reaction of this toxin with monothiols like glutathione could be shown, and the structures of the reaction products were tentatively elucidated by UV and mass spectrometry. Chemical reaction of ATX II with dithiols capable of forming five- and six-membered rings gave rise to ATX I, thus providing a clue for the molecular mechanism of the epoxide reduction pathway of ATX II. Both epoxide reduction and glutathione conjugation appear to attenuate, but not completely abolish, the genotoxicity of ATX II.

The mycotoxin sterigmatocystin (STC) has an aflatoxin-like structure including a furofuran ring system. Like aflatoxin B1, STC is a liver carcinogen and forms DNA adducts after metabolic activation to an epoxide at the furofuran ring. In incubations of STC with human P450 isoforms, one monooxygenated and one dioxygenated STC metabolite were recently reported, and a GSH adduct was formed when GSH was added to the incubations. However, the chemical structures of these metabolites were not unambiguously elucidated. We now report that hepatic microsomes from humans and rats predominantly form the catechol 9-hydroxy-STC via hydroxylation of the aromatic ring. No STC-1,2-oxide and only small amounts of STC-1,2-dihydrodiol were detected in microsomal incubations, suggesting that epoxidation is a minor pathway compared to catechol formation. Catechol formation was also much more pronounced than furofuran epoxidation in the microsomal metabolism of 11-methoxysterigmatocystin (MSTC). In support of the preference of catechol formation, only trace amounts of the thiol adduct of the 1,2-oxides but large amounts of the thiol adducts of the 9-hydroxy-8,9-quinones were obtained when N-acetyl-l-cysteine was added to the microsomal incubations of STC and MSTC. In addition to hydroxylation at C-9, smaller amounts of 12c-hydroxylated, 9,12c-dihydroxylated, and 9,11-dihydroxylated metabolites were formed. Our study suggests that hydroxylation of the aromatic ring, yielding a catechol, represents a major and novel pathway in the oxidative metabolism of STC and MSTC, which may contribute to the toxic and genotoxic effects of these mycotoxins.

The absorption of four Alternaria toxins with perylene quinone structures, i.e. altertoxin (ATX) I and II, alteichin (ALTCH) and stemphyltoxin (STTX) III, has been determined in the Caco-2 cell Transwell system, which represents a widely accepted in vitro model for human intestinal absorption and metabolism. The cells were incubated with the four mycotoxins on the apical side, and the concentration of the toxins in the incubation media of both chambers and in the cell lysate were determined by liquid chromatography coupled with diode array detection and mass spectrometry (LC-DAD-MS) analysis. ATX I and ALTCH were not metabolised in Caco-2 cells, but ATX II and STTX III were partly biotransformed by reductive de-epoxidation to the metabolites ATX I and ALTCH, respectively. Based on the apparent permeability coefficients (Papp), the following ranking order for the permeation into the basolateral compartment was obtained: ATX I > ALTCH >> ATX II > STTX III. Total recovery of the four toxins decreased in the same order. It is assumed that the losses of STTX III, ATX II and ALTCH in Caco-2 cells are caused by covalent binding to cell components due to the epoxide group and/or the α,β-unsaturated carbonyl group present in these toxins. We conclude from this study that ATX I and ALTCH are well absorbed from the intestinal lumen into the portal blood in vivo. For ATX II and STTX III, intestinal absorption of the parent toxins is very low, but these toxins are partly metabolised to ATX I and ALTCH, respectively, in the intestinal epithelium and absorbed as such.

The mycotoxin zearalenone (ZEN) elicits estrogenic effects and is biotransformed to two catechol metabolites, in analogy to the endogenous steroidal estrogen 17ß-estradiol (E2). Previous studies have shown that the catechol metabolites of ZEN have about the same potency to induce oxidative DNA damage as the catechol metabolites of E2, but are less efficiently converted to their methyl ethers by human hepatic catechol-O-methyltransferase (COMT). Here, we report that the two catechol metabolites of ZEN, i.e. 13-hydroxy-ZEN and 15-hydroxy-ZEN, are not only poor substrates of human COMT but are also able to strongly inhibit the O-methylation of 2-hydroxy-E2, the major catechol metabolite of E2. 15-Hydroxy-ZEN acts as a non-competitive inhibitor and is about ten times more potent than 13-hydroxy-ZEN, which is an uncompetitive inhibitor of COMT. The catechol metabolites of ZEN were also shown to inhibit the O-methylation of 2-hydroxy-E2 by hepatic COMT from mouse, rat, steer and piglet, although to a lesser extent than observed with human COMT. The powerful inhibitory effect of catechol metabolites of ZEN on COMT may have implications for the tumorigenic activity of E2, because catechol metabolites of E2 elicit genotoxic effects, and their impaired O-methylation may increase the tumorigenicity of steroidal estrogens.

For studies on the aryl hydrocarbon receptor (AhR)-dependent toxicity of the mycotoxins alternariol (AOH) and alternariol methyl ether (AME), three mouse hepatoma (Hepa-1) cell lines with intact and with compromised AhR signaling were compared with respect to their activities for hydroxylation, methylation, and glucuronidation. Whereas the activities of cytochrome P450-mediated monooxygenase and catechol-O-methyl transferase were very low and did not differ between the three cell lines, a pronounced difference was observed for UDP-glucuronosyl transferase activity, which was much higher in Hepa-1c1c4 than in c1c7 and c1c12 cells. In all three cell types, the rate of glucuronidation of AOH was about four times higher than that of AME. Whereas AME caused a concentration-dependent G2/M arrest in each cell line, AOH arrested Hepa-1c1c7 and c1c12 cells but not c1c4 cells. However, Hepa-1c1c4 cells were arrested by AOH when β-glucuronidase was added to the incubation medium in order to reverse the formation of AOH glucuronides. We conclude that the failure of AOH to cause cell cycle inhibition in Hepa-1c1c4 cells is due to its efficient glucuronidation. The considerable UDP-glucuronosyl transferase activity of Hepa-1c1c4 cells should be taken into account when other compounds are studied in this cell line. Moreover, we demonstrate that differences in glucuronide formation between cell types can be overcome by the addition of β-glucuronidase to the cell culture medium.

Zearalenone (ZEN) is a mycotoxin produced by Fusarium species and frequently found as a contaminant of food and feed. Earlier studies have disclosed that ZEN is biotransformed in microsomes from human and rat liver to multiple hydroxylated metabolites, two of which have recently been identified as products of aromatic hydroxylation. Here, we report for the first time on the structure elucidation of metabolites arising through hydroxylation of the aliphatic ring of ZEN at various positions. By using reference compounds and ZEN labeled with deuterium at specific positions, evidence was provided for the preferential hydroxylation of ZEN at C-8 and, to a lesser extent, at C-9, C-10, and C-5. In contrast, hydroxylation at C-6 could be ruled out, as could oxidation of the olefinic double bond. These results imply that the phase I metabolism of ZEN in the mammalian organism is more extensive than previously thought, and warrant further studies on the in vivo formation of the novel ZEN metabolites and their biological activities.

Zearalenone (ZEN) is a highly estrogenic mycotoxin produced by Fusarium species. The adverse effects of ZEN and its reductive metabolite α-zearalenol (α-ZEL) are often compared to those of 17β-estradiol (E2) and estrone (E1). These endogenous steroidal estrogens are associated with an increased risk for cancer, which may be mediated by two mechanisms, i.e. (1) hormonal activity and (2) genotoxic effects after cytochrome P450-catalyzed metabolic activation to catechols. Like E1 and E2, ZEN and α-ZEL exhibit marked estrogenicity and also undergo aromatic hydroxylation to catechol metabolites. The subsequent methylation of catechols by catechol-O-methyltransferase (COMT) is generally considered as a detoxifying pathway. Imbalances between the activation and inactivation reactions can lead to the formation of reactive semiquinones and quinones, which can alkylate DNA or produce reactive oxygen species by redox cycling. In the present study, the genotoxicity of the catechol metabolites of ZEN, α-ZEL, E1 and E2 was determined in a cell-free system by measuring 8-oxo-2′-deoxyguanosine using a LC-DAD-MS2 method. Each of the individual catechols of ZEN, α-ZEL, E1 and E2 induced oxidative DNA damage in calf thymus DNA. The ranking order of the DNA damaging activity was 15-hydroxy-ZEN/α-ZEL ≈ 2/4-hydroxy-E1/E2 > 13-hydroxy-ZEN/α-ZEL. When hepatic microsomes from different species were incubated with ZEN, the rat had the highest activity for catechol formation, followed by human, mouse, pig and steer. The amount of catechol metabolites correlated directly with the amount of oxidative damage in calf thymus DNA. The ranking order for the rate of methylation by human hepatic COMT was 2-hydroxy-E1/E2 >> 4-hydroxy-E1/E2 >> 13/15-hydroxy-ZEN/α-ZEL. Thus, the catechol metabolites of the mycoestrogen ZEN and its reductive metabolite α-ZEL exhibit a DNA-damaging potential comparable to that of the catechol metabolites of E1 and E2, but are much poorer substrates for inactivation by human COMT.

The Fusarium mycotoxin zearalenone is a frequent contaminant of food and feed. Up to now, different abbreviations and counting systems for the numerous positions of this macrocyclic ß-resorcylic acid lactone and its metabolites have been used. As the number of identified fungal and mammalian metabolites of zearalenone is still growing, the lack of a uniform designation makes the literature on these important toxins confusing and complicated. Here, we propose a logical set of abbreviations and a simple counting system, in order to facilitate future research communications on zearalenone and its congeners.

The mycotoxin zearalenone (ZEN) is produced by various Fusarium fungi and frequently found as a contaminant in food and feed. There are reports in the literature that several closely related analogues of ZEN are also formed in cultures of Fusarium species. We have therefore analyzed the organic extract from a 40 day culture of Fusarium graminearum by LC-DAD-MS and detected 15 compounds, which could be congeners of ZEN because of their ultraviolet, mass spectroscopy, and tandem mass spectroscopy spectra. In addition to confirming the previously reported α- and β-stereoisomers of 5-hydroxy-ZEN and 10-hydroxy-ZEN, we identified seven ZEN congeners for the first time. One of the major novel congeners was shown by nuclear magnetic resonance spectroscopy and chemical synthesis to have the structure of an aliphatic ZEN epoxide, whereas two minor products proved to be the corresponding dihydrodiols. In addition, three stereoisomers of a cyclization product of the dihydrodiols, carrying a spiro-acetal group, were identified as fungal products for the first time. The latter may be artifacts, because the ZEN epoxide and dihydrodiol are unstable under acidic conditions and rearrange easily to the spiro-acetal compounds.

Alternariol (AOH) and alternariol-9-methyl ether (AME) are major toxins produced by fungi of the genus Alternaria. In order to simulate their in vivo intestinal absorption and metabolism, AOH and AME have been studied in differentiated Caco-2 cells and in the Caco-2 Millicell® system in vitro. AOH was found to be readily conjugated to two glucuronides and one sulfate, whereas AME gave rise to one major glucuronide and one sulfate. Whereas the glucuronides of AOH and AME were sequestered about equally well into the basolateral and the apical compartment, the sulfates of both toxins were preferentially released to the apical side. Unconjugated AOH but not AME aglycone reached the basolateral chamber. The apparent permeability coefficients (Papp values) were calculated for the aglycones as well as total mycotoxin-associated compounds using an initial apical concentration of 20 µmol/l AOH or AME. Based on these Papp values, AOH must be expected to be extensively and rapidly absorbed from the intestinal lumen in vivo and reach the portal blood both as aglycone and as glucuronide and sulfate. In contrast, intestinal absorption of AME appears to be poor and sluggish, with no AME agylcone and only AME conjugates reaching the portal blood.

α-Zearalanol (α-ZAL, zeranol) is a highly estrogenic macrocyclic β-resorcylic acid lactone, which is used as a growth promotor for cattle in various countries. We have recently reported that α-ZAL and its major metabolite zearalanone (ZAN) are hydroxylated at the aromatic ring by microsomes from human liver in vitro, thereby forming two catechol metabolites each. Thus, the oxidative metabolism of α-ZAL and ZAN resembles that of the endogenous steroidal estrogens 17β-estradiol (E2) and estrone (E1), which also give rise to two catechols each. As these catechol metabolites are believed to mediate the carcinogenicity of E2 and E1 by causing oxidative DNA damage and DNA adducts, their methylation by catechol-O-methyltransferase (COMT) is an important inactivation pathway. Here we report that hepatic microsomes from five species generate catechol metabolites of α-ZAL and ZAN, the highest amounts being formed by human liver microsomes, followed by rat, mouse, steer and swine. The microsomal extracts and the individual catechols of α-ZAL, ZAN, E2 and E1 were found to induce oxidative DNA damage, as measured by the formation of 8-oxo-7,8-dihydro-2′-deoxyguanosine in a cell-free system. The ranking of pro-oxidant activity was 15-HO-ZAN > 15-HO-α-ZAL ≈ 4-HO-E2/E1 ≈ 2-HO-E2/E1 > 13-HO-ZAN > 13-HO-α-ZAL. With respect to the rate of methylation by human hepatic COMT, the ranking was 2-HO-E2/E1 >> 4-HO-E2/E1 > 15-HO-α-ZAL/ZAN >> 13-HO-α-ZAL/ZAN. Thus, some catechol metabolites of α-ZAL and ZAN are better pro-oxidants and poorer substrates of COMT than the catechols of E2 and E1. These findings warrant further investigations into the genotoxic potential of α-ZAL, which may constitute another biological activity in addition to its well-known estrogenicity.Highlights► Zeranol (ZAL) and its metabolite zearalanone (ZAN) form catechol metabolites. ► ZAL/ZAN catechols induce oxidative DNA damage in vitro. ► ZAL/ZAN catechols are stronger pro-oxidants than catechols of estradiol/estrone (E2/E1). ► ZAL/ZAN catechols are less efficiently methylated by COMT than E2/E1 catechols.

α-Zearalanol (α-ZAL, zeranol) is a macrocyclic resorcylic acid lactone, which is highly estrogenic and used as a growth promotor for cattle in various countries. Little is known about the phase I metabolism of α-ZAL. We now report that α-ZAL and its major metabolite zearalanone (ZAN) are extensively monohydroxylated at the aromatic ring by microsomes from human liver in vitro. This novel pathway leads to catechols, the chemical structures of which were unambiguously established by the use of deuterium-labeled α-ZAL and ZAN, and by the synthesis of authentic standards. The aromatic hydroxylation of α-ZAL is almost exclusively mediated by the human cytochrome P450 (hCYP) 1A2 isoform. The catechol metabolites of α-ZAL and ZAN are unstable and readily oxidized to quinones, which could be detected among the metabolites of α-ZAL and ZAN generated by human hepatic microsomes and hCYP1A2. Furthermore, the quinone metabolites are able to form covalent adducts with N-acetylcysteine (NAC), as several of such adducts were found in microsomal incubations fortified with NAC. Aromatic hydroxylation of α-ZAL was also observed with bovine, porcine and rat hepatic microsomes. Further studies are needed to demonstrate the catechol pathway of α-ZAL in vivo and to assess its toxicological significance.