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In vivo assembly enhanced binding effect augments tumor specific ferroptosis therapy.

Da-Yong HouDong-Bing ChengNi-Yuan ZhangZhi-Jia WangXing-Jie HuXin LiMei-Yu LvXiang-Peng LiLing-Rui JianJin-Peng MaTaolei SunZeng-Ying QiaoWanhai XuHao Wang
Published in: Nature communications (2024)
Emerging evidence indicates that the activation of ferroptosis by glutathione peroxidase 4 (GPX4) inhibitors may be a prominent therapeutic strategy for tumor suppression. However, the wide application of GPX4 inhibitors in tumor therapy is hampered due to poor tumor delivery efficacy and the nonspecific activation of ferroptosis. Taking advantage of in vivo self-assembly, we develop a peptide-ferriporphyrin conjugate with tumor microenvironment specific activation to improve tumor penetration, endocytosis and GPX4 inhibition, ultimately enhancing its anticancer activity via ferroptosis. Briefly, a GPX4 inhibitory peptide is conjugated with an assembled peptide linker decorated with a pH-sensitive moiety and ferriporphyrin to produce the peptide-ferriporphyrin conjugate (Gi-F-CAA). Under the acidic microenvironment of the tumor, the Gi-F-CAA self-assembles into large nanoparticles (Gi-F) due to enhanced hydrophobic interaction after hydrolysis of CAA, improving tumor endocytosis efficiency. Importantly, Gi-F exhibits substantial inhibition of GPX4 activity by assembly enhanced binding (AEB) effect, augmenting the oxidative stress of ferriporphyrin-based Fenton reaction, ultimately enabling antitumor properties in multiple tumor models. Our findings suggest that this peptide-ferriporphyrin conjugate design with AEB effect can improve the therapeutic effect via induction of ferroptosis, providing an alternative strategy for overcoming chemoresistance.
Keyphrases
  • cell death
  • oxidative stress
  • dna damage
  • hydrogen peroxide
  • cancer therapy
  • signaling pathway
  • endoplasmic reticulum stress
  • smoking cessation
  • dna binding
  • replacement therapy