Shipin gongye ke-ji (Nov 2024)

Effects of Carbon Nitride Combined with Chitosan on Lipid Metabolism of Salmonella Typhimurium

  • Yanyan WANG,
  • Xingning XIAO,
  • Jian LI,
  • Jiele MA,
  • Xiaoping DONG,
  • Zhengkai YI,
  • Qiaoming LOU,
  • Wen WANG

DOI
https://doi.org/10.13386/j.issn1002-0306.2023120142
Journal volume & issue
Vol. 45, no. 22
pp. 208 – 216

Abstract

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Objective: To investigate the bactericidal mechanism of a composite sol made of carbon nitride and chitosan on Salmonella typhimurium by studying its effects on lipid metabolism. Methods: Transmission electron microscopy and protein leakage concentration were utilized to evaluate the magnitude of cell membrane damage induced by carbon nitride-chitosan composite sol at a cellular level. In addition, lipid metabolomics was employed to investigate the bactericidal process by examining several metabolite functions and regulatory networks associated with bacterial lipid metabolism. Results: The composite sol of carbon nitride-chitosan caused more extensive damage to the cell membrane of Salmonella typhimurium. In lipid metabolism, the significantly up-regulated in 203 metabolites and down-regulated in 95 metabolites. These metabolites were particularly involved in the metabolism of fatty acids, glycerophospholipids, and glycolipids. Metabolite function analysis showed that the composite sol treatment disrupted various metabolic pathways in bacteria. These pathways included fatty acid biosynthesis, glycerol phospholipid metabolism, linoleic acid metabolism, tetraenoic acid metabolism, as well as pathways related to cell energy metabolism, material transport, and signal conduction. These disturbances finally resulted in the demise of the bacteria. Conclusion: This study revealed from the perspective of lipid metabolism that the combination of carbon nitride and chitosan disrupts the metabolic pathways of Salmonella, especially those related to lipid metabolism, leading to bacterial metabolic disruption and death. It provides a theoretical basis for comprehending the mechanisms by which photocatalytic materials exert their antibacterial properties.

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