Metabolism of aflatoxin B1 in the bovine olfactory mucosa

Abstract

Carcinomas of the ethmoidal region of the nose are observed relatively frequently in cattle in several countries in tropical and subtropical latitudes. Viruses have been implicated as causative agents, but it has been observed that affected animals sometimes suffer from aflatoxicosis, and a role of aflatoxin B1 (AFB1) in the aetiology has also been proposed. We have examined whether the bovine nasal olfactory mucosa has a capacity to metabolize AFB1. The contents of cytochrome P-450 and cytochrome b5, and the NADPH cytochrome c reductase activity in the nasal olfactory mucosa have also been determined. Comparative experiments have been performed with the liver. Incubations with 3H-labelled AFB1 showed that the nasal olfactory mucosa has a much higher capacity than the liver to form lipid-soluble, water-soluble and tissue-bound AFB1-metabolites. High-resolution microautoradiography showed a strong localization of tissue-bound metabolites in the sustentacular cells in the apical portion of the olfactory surface epithelium and in Bowman''s glands in the olfactory lamina propria mucosae. Especially in the sustentacular cells the labelling was preferentially located in the nuclei of the cells. Liquid chromatography of chloroform extracts of the nasal olfactory mucosa and the liver incubated with 3H-AFB1 showed formation of several metabolites. The dominating peak in both tissues was aflotoxin M1 (AFM1). However, the amount of AFM1 was higher in the nasal olfactory mucosa than in the liver, and the amounts and proportions of several other metabolites also differed markedly between the two tissues. The level of cytochrome P-450 in the nasal olfactory mucosa was found to be about one quarter of that in the liver, but the NADPH cytochrome c reductase activity was much higher in the nasal olfactory mucosa than in the liver. In addition, the cytochrome b5: cytochrome P-450 ratio was higher in the nasal olfactory mucosa than in the liver. The higher metabolism of AFB1 in the nasal olfactory mucosa than in the liver may be related to differences in the cytochrome P-450 isoenzyme profile. In addition, the microsomal electron transport to cytochrome P-450 may be facilitated by the high reductase: cytochrome P-450 ratio and the high cytochrome b5: cytochrome P-450 ratio in the nasal olfactory mucosa. It is considered that the results of the present study strengthen the hypothesis that exposure of AFB1-contaminated feed may be an important aetiological factor in the development of nasal tumours in cattle.