Conductive coordination nanozyme prodrugs precisely trigger pyroptosis, cuproptosis and ferroptosis for in situ cancer vaccination
Summary
Pyroptosis, which rapidly releases cellular contents through pyroptotic pores, is an ideal method for inducing in situ cancer vaccines, evoking systemic antitumor immunity, and suppressing primary and metastatic tumors. However, the clinical translation of pyroptosis-based therapy is hindered by the inability to spatially control the activation of inert precursors and the inefficient catalytic activity of nanozymes, which often fail to generate sufficient reactive oxygen species for effect
Content
# Conductive coordination nanozyme prodrugs precisely trigger pyroptosis, cuproptosis and ferroptosis for in situ cancer vaccination
*Published: 2026 Mar 16*
Pyroptosis, which rapidly releases cellular contents through pyroptotic pores,
is an ideal method for inducing in situ cancer vaccines, evoking systemic
antitumor immunity, and suppressing primary and metastatic tumors. However, the
clinical translation of pyroptosis-based therapy is hindered by the inability to
spatially control the activation of inert precursors and the inefficient
catalytic activity of nanozymes, which often fail to generate sufficient
reactive oxygen species for effective treatment. To address this, we designed a
conductive coordination nanozyme prodrug, Cu-DHN. Its π-conjugated polyphenol
backbone functions as an intrinsic "electron highway," enabling rapid electron
shuttling to utilize the entire nanoparticle volume for catalysis, thereby
achieving exceptional peroxidase-like activity. Upon systemic administration,
Cu-DHN remains inert in circulation but is precisely activated within the tumor
microenvironment by a tandem GSH-depletion and H2O2-responsive logic gate. This
triggers a self-cascade reaction that locally transforms the coordinated prodrug
into juglone, which concurrently reverses gasdermin D epigenetic silencing and
activates the NLRP3 inflammasome for caspase-1-mediated cleavage. This
single-agent, tumor-specific initiation of pyroptosis, augmented by concomitant
cuproptosis, elicits potent immunogenic cell death and robust systemic antitumor
immunity, effectively suppressing primary and metastatic tumors while exhibiting
a pristine safety profile. Our work establishes electron-shuttling coordination
polymers as a versatile platform for developing safe and potent catalytic
immunotherapies.
DOI: 10.1038/s41392-026-02607-6