Frontiers in Pharmacology (Aug 2021)

A Systematic Study of the Mechanism of Acacetin Against Sepsis Based on Network Pharmacology and Experimental Validation

  • Yuanshuo Ouyang,
  • Yuanshuo Ouyang,
  • Yuanshuo Ouyang,
  • Yi Rong,
  • Yi Rong,
  • Yi Rong,
  • Yanming Wang,
  • Yanming Wang,
  • Yanming Wang,
  • Yanli Guo,
  • Yanli Guo,
  • Yanli Guo,
  • Liya Shan,
  • Liya Shan,
  • Liya Shan,
  • Xiushi Yu,
  • Xiushi Yu,
  • Xiushi Yu,
  • Li Li,
  • Junqiang Si,
  • Junqiang Si,
  • Junqiang Si,
  • Xinzhi Li,
  • Xinzhi Li,
  • Xinzhi Li,
  • Ketao Ma,
  • Ketao Ma,
  • Ketao Ma

DOI
https://doi.org/10.3389/fphar.2021.683645
Journal volume & issue
Vol. 12

Abstract

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Sepsis is a dysregulated systemic response to infection, and no effective treatment options are available. Acacetin is a natural flavonoid found in various plants, including Sparganii rhizoma, Sargentodoxa cuneata and Patrinia scabiosifolia. Studies have revealed that acacetin potentially exerts anti-inflammatory and antioxidative effects on sepsis. In this study, we investigated the potential protective effect of acacetin on sepsis and revealed the underlying mechanisms using a network pharmacology approach coupled with experimental validation and molecular docking. First, we found that acacetin significantly suppressed pathological damage and pro-inflammatory cytokine expression in mice with LPS-induced fulminant hepatic failure and acute lung injury, and in vitro experiments further confirmed that acacetin attenuated LPS-induced M1 polarization. Then, network pharmacology screening revealed EGFR, PTGS2, SRC and ESR1 as the top four overlapping targets in a PPI network, and GO and KEGG analyses revealed the top 20 enriched biological processes and signalling pathways associated with the therapeutic effects of acacetin on sepsis. Further network pharmacological analysis indicated that gap junctions may be highly involved in the protective effects of acacetin on sepsis. Finally, molecular docking verified that acacetin bound to the active sites of the four targets predicted by network pharmacology, and in vitro experiments further confirmed that acacetin significantly inhibited the upregulation of p-src induced by LPS and attenuated LPS-induced M1 polarization through gap junctions. Taken together, our results indicate that acacetin may protect against sepsis via a mechanism involving multiple targets and pathways and that gap junctions may be highly involved in this process.

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