Abstract
Difenoconazole (DIF) is a widely separated triazole fungicide in many countries. The excessive usage of DIF increases the high volume of residues in agriculture production and water bodies. Some previous studies demonstrated the toxic effects of DIF on non-target animals, however, there were still some gaps in the knowledge of the potential hazards of DIF to mammals and human health. Herein, 7-week-old male mice were exposed to 30 and 100 mg/kg/day DIF for 14 and 56 days. We observed that 56 days of DIF exposure decreased the colonic mucus expression of alcin blue-periodic acid-schiff (AB-PAS) stain and the immunochemical stain of muc2 protein. The transcript levels of mucin protein (muc1, muc2 and muc3) decreased significantly in the gut of mice followed 56 days of 100 mg/kg/day DIF exposure. In addition, the gut microbiota composition was also affected after 14 or 56 days of DIF exposure. Although the mucus expression after 14 days of DIF exposure only decreased slightly, the gut microbiota composition compared with the control group was changed significantly. Moreover, the DIF-30 and DIF-100 caused respectively different changes on the gut microbiota. The relative abundance of Bacteroidetes decreased significantly after 14 days and 56 days of DIF exposure. After 14 days of DIF exposure, there were 35 and 18 differential genera in the DIF-30 and DIF-100 group, respectively. There were 25 and 32 differential genera in the DIF-30 and DIF-100 group after 56 days of exposure, respectively. Meanwhile, the alpha diversity indexes, including observed species, Shannon, Simpson, Chao1 and ACE, in gut microbiota decreased significantly after 56 days of DIF exposure. Interestingly, the relative abundance of Akkermansia increased significantly after 56 days of 100 mg/kg/d DIF exposure. Although Akkermansia was considered as one probiotic, the phenomenon of dramatic Akkermansia increase with the decrease in gut microbiota diversity needed further discussion. These results provided some new insights on how DIF exposure impacts the mucus barrier and induces gut microbiota dysbiosis.
Highlights
Triazole fungicides can effectively control pathogen fungus by inhibiting the C14demethylase in sterol synthesis
Akkermansia was considered as one probiotic, the phenomenon of dramatic Akkermansia increase with the decrease in gut microbiota diversity needed further discussion
These results provided some new insights on how DIF exposure impacts the mucus barrier and induces gut microbiota dysbiosis
Summary
Triazole fungicides can effectively control pathogen fungus by inhibiting the C14demethylase in sterol synthesis. Especially ergosterol, play important roles in the cell membrane formation. The lack of sterols inhibited by triazole fungicides causes abnormal fungal growth, even death. Difenoconazole (DIF) is an internal absorption triazole fungicide. Due to its highly efficient and broad spectrum, DIF is widely used worldwide to combat fungal diseases [1]. With the wide usage of DIF, DIF residue was frequently detected in agriculture production. Cui et al showed that DIF was frequently detected in a total of 3406 fruit and vegetable samples, especially in cowpea (60.30%, maximum 343.39 μg/kg), grape (68.70%, maximum 803.30 μg/kg) and mandarin (64.34%, maximum 192.70 μg/kg) [2]. DIF was detected in 43% of tomato crops (maximum 64.3 μg/kg) in Western Algeria [3]
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
