Immune activation within tumors is governed by highly dynamic redox and mitochondrial signaling events, yet the temporal organization of these processes remains poorly defined. Here, we report a programmable DNAzyme nanocatalyst (APTZ) that enables time-dependent redox-immune coupling by translating intracellular catalytic activity into a transient biochemical signal window. The APTZ platform integrates ZnO nanoparticles, a catalase-targeting DNAzyme, and a tumor-homing aptamer, allowing acid-triggered Zn2+ release to induce sequence-specific catalytic cleavage of catalase mRNA. This reaction amplifies intracellular reactive oxygen species while depleting glutathione, leading to mitochondrial membrane depolarization, energetic collapse, and cytosolic release of mitochondrial DNA. The resulting mtDNA leakage activates the cGAS-STING pathway and induces a robust type I interferon response, thereby establishing a transient 4-6 h redox sensitization window. Leveraging this temporally confined state enhances dendritic-cell maturation and cytotoxic T-cell infiltration when immune checkpoint blockade is applied within the defined window. Conceptually, this work demonstrates that programmable DNAzyme catalysis can be harnessed to generate actionable temporal biochemical cues, providing a nanobiotechnology framework for time-guided innate immune modulation and highlighting the broader potential of DNAzyme-based nanocatalysts in dynamic cancer immunotherapy .
Wang et al. (Tue,) studied this question.