The complex microbial community in food environment is a major problem of human or animal health and safety. Mycotoxins and food-borne bacteria can both induce inflammation in the body and cause a series of changes in biological functions. In this study, mice were gavaged with low doses of ZEA, DON, or ZEA + DON, and then infected with L. monocytogenes. A cytokine microarray, including 40 inflammation-related serum cytokines, and proteomics were used to verify the effects of ZEA, DON, and ZEA + DON on the host inflammation and biological function after L. monocytogenes infection. The results showed that mononucleosis after bacterial infection was inhibited by ZEA, DON, and ZEA + DON, while the balance of macrophage differentiation was shifted toward M2-type. ZEA, DON, and ZEA + DON decreased the levels of serum proinflammatory cytokines IL-1β and IL-12 after infection. In addition, the signal of the NF-κB pathway was inhibited. Proteomic results showed that ZEA, DON, and ZEA + DON led to biological dysfunction in ribosomal and metabolic cells, primarily leading to abnormal ribosomal hyperfunction. This study showed that ZEA, DON, and ZEA + DON can aggravate disease progression by inhibiting the inflammatory response following foodborne bacterial infection. These metabolites may also disrupt normal biological functions, which may lead to ribosomal hyperfunction, making bacterial clearance more difficult.
Keywords: Deoxynivalenol; Inflammation; Listeria monocytogenes; Ribosomal hyperfunction; Zearalenone.
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