SCOPE: Monohydroxylation of alternariol (AOH) and alternariol-9-methyl ether (AME) has previously been reported as a prominent metabolic route under cell-free conditions. This pathway gives rise to several catechol metabolites and may therefore be of toxicological relevance. METHODS AND RESULTS: To clarify whether hydroxylation of AOH and AME occurs under in vivo-like conditions in the presence of conjugation reactions, the metabolism of the Alternaria toxins has now been studied in precision-cut rat liver slices. Four catechol metabolites of AOH and two of AME, together with several of their O-methylation products, as catalyzed by catechol-O-methyl transferase, were clearly identified after incubation of the liver slices with AOH and AME. These metabolites were predominantly present as conjugates with glucuronic acid and/or sulfate. In preliminary studies with bile duct-cannulated male rats dosed with AOH by gavage, the four monohydroxylated metabolites of AOH could also be demonstrated in the bile either as catechols or as O-methyl ethers. CONCLUSION: These experiments clearly show that AOH and AME undergo catechol formation in vivo and warrant closer examination of the toxicological significance of this metabolic pathway.
SCOPE: Monohydroxylation of alternariol (AOH) and alternariol-9-methyl ether (AME) has previously been reported as a prominent metabolic route under cell-free conditions. This pathway gives rise to several catechol metabolites and may therefore be of toxicological relevance. METHODS AND RESULTS: To clarify whether hydroxylation of AOH and AME occurs under in vivo-like conditions in the presence of conjugation reactions, the metabolism of the Alternaria toxins has now been studied in precision-cut rat liver slices. Four catechol metabolites of AOH and two of AME, together with several of their O-methylation products, as catalyzed by catechol-O-methyl transferase, were clearly identified after incubation of the liver slices with AOH and AME. These metabolites were predominantly present as conjugates with glucuronic acid and/or sulfate. In preliminary studies with bile duct-cannulated male rats dosed with AOH by gavage, the four monohydroxylated metabolites of AOH could also be demonstrated in the bile either as catechols or as O-methyl ethers. CONCLUSION: These experiments clearly show that AOH and AME undergo catechol formation in vivo and warrant closer examination of the toxicological significance of this metabolic pathway.