Nothing Special   »   [go: up one dir, main page]

Bioorthogonal catalytic nanozyme-mediated lysosomal membrane leakage for targeted drug delivery

Theranostics. 2022 Jan 1;12(3):1132-1147. doi: 10.7150/thno.66325. eCollection 2022.

Abstract

Rationale: Employing in situ bioorthogonal catalysis within subcellular organelles, such as lysosomes, remains a challenge. Lysosomal membranes pose an intracellular barrier for drug sequestration, thereby greatly limiting drug accumulation and concentrations at intended targets. Here, we provide a proof-of-concept report of a nanozyme-based strategy that mediates in situ bioorthogonal uncaging reactions within lysosomes, followed by lysosomal escape and the release of uncaged drugs into the cytoplasm. Methods: A model system composed of a protein-based nanozyme platform (based on the transition metals Co, Fe, Mn, Rh, Ir, Pt, Au, Ru and Pd) and caged compound fluorophores was designed to screen for nanozyme/protecting group pairings. The optimized nanozyme/protecting group pairing was then selected for utilization in the design of anti-cancer pro-drugs and drug delivery systems. Results: Our screening system identified Pd nanozymes that mimic mutant P450BM3 activity and specifically cleave propargylic ether groups. We found that the intrinsic peroxidase-like activity of Pd nanozymes induced the production of free radicals under acid conditions, resulting in lysosomal membrane leakage of uncaged molecules into the cytoplasm. Using a multienzyme synergistic approach, our Pd nanozymes achieved in situ bioorthogonal catalysis and nanozyme-mediated lysosomal membrane leakage, which were successfully applied to the design of model pro-drugs for anti-cancer therapy. The extension of our nanozyme system to the construction of a liposome-based "all-in-one" delivery system offers promise for realizing efficacious in vivo tumor-targeted therapies. Conclusions: This strategy shows a promising new direction by utilizing nanotechnology for drug development through in situ catalyzing bioorthogonal chemistry within specific subcellular organelles.

Keywords: Bioorthogonal catalysis; Lysosome; Nanozyme; Pro-drug; Targeted delivery; Tumor.

Publication types

  • Research Support, Non-U.S. Gov't

MeSH terms

  • Catalysis
  • Humans
  • Lysosomes
  • Neoplasms*
  • Prodrugs*

Substances

  • Prodrugs