Copper (Cu) is an essential trace element, but it is also a ubiquitous environmental pollutant that threatens public health. Cuproptosis is a recently discovered cell death mode that unlike other programmed cell death, characterized by proteotoxic stress due to lipoylated protein aggregation and iron-sulfur cluster protein loss. Chickens as a high-trophic-level non-mammalian vertebrate that easily absorb and accumulate copper from the environment and food, but it is unclear whether the underlying molecular mechanisms that cause their hepatotoxicity under natural copper stress are related to cuproptosis. Therefore, we established animal models of chickens with different concentrations of copper exposure to dissect the role and mechanism of cuproptosis in chicken hepatotoxicity under natural copper stress. Our histopathological and biochemical results demonstrated that the liver structure with copper-treated exhibited dose-dependent damage. Meanwhile, copper treatment also dramatically increased serum and liver copper content and activated the expression of the membrane-associated copper transporter ATP7B. Furthermore, we found that Cu-exposure significantly increased the MDA content, and reduced the levels of T-AOC and SOD in serum and liver. Additionally, we found that the mRNA and protein levels of FDX1 were significantly upregulated in the 220 and 330 mg/kg Cu-treated groups. In our further studies, we found that copper did not alter protein levels of DLAT and DLST in chicken liver, but significantly increased Lipoylated-DLAT levels and oligomerization of Lipoylated-DLAT in the 330 mg/kg Cu-treatment group. Overall, we identified that FDX1-mediated protein lipoylation and proteotoxic stress indeed participate in copper-induced hepatotoxicity in chickens. Our results present novel insight into the pathogenesis of copper-induced hepatotoxicity in chickens and provide data to support filling in the role of cuproptosis in birds.
Keywords: Chicken; Copper; Cuproptosis; FDX1; Hepatotoxicity.
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