Influence of toxic metal exposure on the gut microbiota (Review) Original paper

What was studied?

The study explores the impact of pharmacological doses of copper on the microbial communities in the hindgut and the antimicrobial resistance profiles of Escherichia coli in weaned piglets. Specifically, the study aims to investigate how copper supplementation affects microbial diversity and composition in the ileum and cecum, as well as the resistance of E. coli strains to common antibiotics.

Who was studied?

The research focused on twenty-four healthy, weaned piglets aged 21 ± 1 days, with an average weight of 7.27 ± 0.46 kg. These piglets were randomly divided into four groups. One group received a basal diet, while the other groups were given diets supplemented with varying doses of copper (20, 100, or 200 mg copper/kg feed, in the form of CuSO4).

Most important findings

The study demonstrated that while copper supplementation did not significantly affect the diversity of the microbial communities in the piglets’ gastrointestinal tract, it did notably alter their composition. Copper supplementation influenced the microbial metabolic functions related to energy metabolism, protein metabolism, and amino acid biosynthesis. Moreover, the study found that copper treatment increased the abundance of E. coli in the hindgut. Additionally, E. coli strains isolated from the copper-treated groups exhibited higher resistance to antibiotics such as chloramphenicol and ciprofloxacin. The resistance of E. coli to multiple drugs also increased in the ileum of the piglets, highlighting a potential risk of promoting antimicrobial resistance in agricultural settings.

Key implications

The findings from this study have significant implications for animal agriculture and public health. The observed increase in E. coli resistance to antibiotics in response to high copper intake raises concerns about the potential role of copper in promoting antimicrobial resistance. This is particularly important as resistant strains of E. coli may pose a risk to human health through the food chain. Additionally, the altered microbial composition in the gut due to copper supplementation suggests that long-term exposure to pharmacological copper doses could lead to shifts in gut microbiota, possibly impacting host health. Therefore, careful management of copper supplementation in livestock is recommended to avoid unintended consequences, such as the development of antimicrobial resistance.