Methimazole is a compound administered to humans for the treatment of hyperthyroidism and is used experimentally as a model substrate for the flavin-containing monooxygenase (FMO) system. Previous results from this laboratory demonstrated that methimazole is an olfactory system toxicant, causing nearly complete destruction of the olfactory epithelium in the male Long-Evans rat following a single ip dose of 300 mg/kg.The present studies were undertaken to determine the dose-response relationship for methimazole-induced olfactory mucosal damage and to determine whether or not similar damage occurs as a result of oral administration, mimicking the relevant route of human exposure. We also investigated the mechanism of olfactory toxicity of methimazole by means of a structure-activity study and began the characterization of the form(s) of FMO present in the olfactory mucosa of the male Long-Evans rat. Dose-response analysis demonstrated that methimazole causes olfactory mucosal damage at doses of 25 mg/kg ip and greater. The results of gavage studies showed that a single oral dose of 50 mg/kg also caused olfactory mucosal damage. Two structurally related compounds, methylimidazole and methylpyrrole, were not olfactory toxicants, suggesting that a reactive intermediate generated in the course of metabolizing methimazole to an S-oxide is the olfactory toxic species. Microsomal incubation studies revealed the presence ofmethimazole S-oxidation activity in olfactory mucosal microsomes at levels comparable to those in liver. An anti-mouse liver FMO antibody reacted on Western blots with olfactory mucosal microsomes. These findings demonstrate a doseresponse for the olfactory toxicity of methimazole and suggest that characterization of human olfactory mucosal FMO activity may be necessary to assess the potential for human risk associated with therapeutic exposure to methimazole.
Pesticides are high-volume, widely used, environmental chemicals and there is continuous debate concerning their possible role in many chronic human health effects. Because of their known structures, known rates of application, and the presence of a large occupationally exposed population, they are not only important in their own right but are ideal models for the effects of environmental chemicals on the population in general. For reasons that are not always clear, this potential has not been realized. These exposed populations represent an underused asset in the study of the human health effects of environmental contaminants. Chronic effects thought to involve pesticides include carcinogenesis, neurotoxicity, and reproductive and development effects. In this paper we attempt to summarize this concern and, relying to a large extent on studies in our own laboratory, to indicate the importance and present status of studies of the mammalian metabolism of pesticides and indicate the need for further use of this model. Aspects considered include the role of pesticides as substrates for xenobiotic-metabolizing enzymes such as cytochrome P450 and the flavin-containing monooxygenase and their role as inducers or inhibitors of metabolic enzymes. The interaction of pesticides with complex multienzyme pathways, the role of biological characteristics, particularly gender, in pesticide metabolism, and the special role of pesticides at portals of entry and in target tissues are also considered.
Hepatic flavin-containing monooxygenase (FMO) activity of microsomes from adult CD-1, Swiss-Webster, C57BL/6, and DBA/2 mice was found to be significantly higher in females than in males. Based on protein and mRNA levels in CD-1 mice, FMO forms responsible for the gender difference in FMO activity were FMO1 and FMO3. FMO1 expression was two to three times higher in female mice compared with males; FMO3, however, which was expressed at levels equivalent to FMO1 in female mice, was not detected in males. The expression of FMO5 was approximately equal in both sexes. FMO2 and FMO4 transcripts were not evident in hepatic mRNA from mice. Protein and mRNA levels appear to be coregulated with regard to gender-selective or gender-specific expression of FMO1 or FMO3, respectively. FMO5, which demonstrates no gender-selective expression in mice, may be regulated by different mechanisms. Examination of protein levels among Swiss-Webster, C57BL/6, and DBA/2 strains revealed a gender-dependent expression of FMO isozymes identical to the CD-1 strain.
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