Fumonisin B<sub>1</sub> Exposure Causes Intestinal Tissue Damage by Triggering Oxidative Stress Pathways and Inducing Associated CYP Isoenzymes

Fumonisin B<sub>1</sub> Exposure Causes Intestinal Tissue Damage by Triggering Oxidative Stress Pathways and Inducing Associated CYP Isoenzymes

Fumonisin B<sub>1</sub> (FB<sub>1</sub>) is considered the most toxic fumonisin produced by fungi and is commonly found in contaminated feed and crops. Fumonisin and its metabolites extensively exist in feed and crops, where FB<sub>1</sub>-polluted crop ingestion...

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Bibliographic Details
Main Authors: Changyu Cao, Weiping Hua, Runxi Xian, Yang Liu
Format: Article
Language:English
Published: MDPI AG 2025-05-01
Series:Toxins
Subjects:
Fumonisin B<sub>1</sub>
intestinal
oxidative stress
Cytochrome P450 proteins
NXRs
Online Access:https://www.mdpi.com/2072-6651/17/5/239
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Summary:Fumonisin B<sub>1</sub> (FB<sub>1</sub>) is considered the most toxic fumonisin produced by fungi and is commonly found in contaminated feed and crops. Fumonisin and its metabolites extensively exist in feed and crops, where FB<sub>1</sub>-polluted crop ingestion can do harm to livestock and poultry, causing poultry intestinal toxicity in the latter. For investigating FB<sub>1</sub>-mediated intestinal toxicity, we assessed the function of FB<sub>1</sub> exposure in quail intestines and explored its possible molecular mechanisms. In total, 120 quail pups were classified into two groups, where those in the control group were given a typical control diet, and those in the experimental group were given a typical diet that contained 30 mg/kg FB<sub>1</sub>. We evaluated the histopathological and ultrastructural changes in quails’ intestines on days 14, 28, and 42, and studied the molecular mechanisms by assessing oxidative stress, inflammation, and nuclear xenobiotic receptors (NXRs). Our results suggest that FB<sub>1</sub> exposure causes intestinal inflammation by triggering oxidative stress pathways and modulating NXRs to induce Cytochrome P450 proteins (CYP) isoforms, leading to intestinal histopathological damage. The results of this study shed novel light on the molecular mechanism underlying FB<sub>1</sub>-induced intestinal injury in juvenile quails.
ISSN:2072-6651

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