Abstract

Background: Podophyllotoxin (PPT), a highly active compound extracted from the rhizome of Dysosma versipellis (DV), has been used as an effective anti-cancer drug clinically since the 1950s. It possesses various biological activities, including antiviral and antitumor effects. However, its clinical application is severely limited due to its hepatotoxicity, and the underlying mechanisms remain unclear. This study aims to elucidate the mechanisms of PPT-induced hepatotoxicity using tandem quality tag (TMT) based quantitative proteomics and phosphoproteomics, providing potential targets and directions for developing new therapeutic strategies to facilitate the safe and rational use of podophyllotoxin in clinical settings.

Methods: We employed a comprehensive assessment of PPT-induced hepatotoxicity based on the Toxicology Evidence Chain (TEC) concept, originally proposed by our research group in 2018. This approach involves a tiered search for evidence of Harmful Ingredients Evidence (HIE), Injury Phenotype Evidence (IPE), Adverse Outcomes Evidence (AOE), and Toxic Events Evidence (TEE) during the development of PPT-induced hepatotoxicity, thereby constructing a guiding toxicology evidence chain. Sprague-Dawley (SD) rats were administered 20?mg/kg PPT for 4 consecutive days (HIE). Indicators such as hepatic function, oxidative stress, inflammatory factors, as well as the histopathology of liver tissue were evaluated to assess liver damage and synthetic function (AOE). Proteomics and phosphoproteomics were conducted to systematically assess PPT-induced hepatotoxicity at the level of modified proteins and verify the molecular mechanisms of key molecular pathways (TEE1). Furthermore, in vitro THLE-2 cell models were used in conjunction with CCK8, immunofluorescence, and ELISA assays to validate cytotoxicity and its underlying mechanisms (TEE2).

Results: Our results showed that after 4 days of PPT administration at 20?mg/kg (HIE), serum levels of AST/ALT, TBA, TP, and ALB in SD rats were significantly increased (P?

Conclusion: PPT activates the complement system through the C5a/C5aR/ROS/NLRP3 pathway and induces the formation of inflammasomes, promoting pyroptosis. Simultaneously, PPT activates the cGMP-PKG pathway, inhibiting autophagy and further accelerating pyroptosis, ultimately leading to hepatotoxicity. In conclusion, this study comprehensively revealed the underlying mechanisms of PPT-induced hepatotoxicity using the TEC concept. This approach transforms fragmented toxicity indicators into systematic evidence of toxicity, presenting a hierarchical progression of toxicity evidence and avoiding data accumulation in natural drug toxicology. Our findings represent a significant breakthrough in the elucidation of the mechanisms of hepatotoxicity induced by podophyllotoxin.