Genotype-specific precision tumor therapy using mitochondrial DNA mutation-induced drug release system.
Yanan LiRu XuYonghua WuJialing GuoFenglei QuanYiran PeiDi HuangXiu ZhaoHua GaoJunjie LiuZhenzhong ZhangJinjin ShiKaixiang ZhangPublished in: Science advances (2023)
Precise killing of tumor cells without affecting surrounding normal cells is a challenge. Mitochondrial DNA (mtDNA) mutations, a common genetic variant in cancer, can directly affect metabolic homeostasis, serving as an ideal regulatory switch for precise tumor therapy. Here, we designed a mutation-induced drug release system (MIDRS), using the single-nucleotide variation (SNV) recognition ability and trans-cleavage activity of Cas12a to convert tumor-specific mtDNA mutations into a regulatory switch for intracellular drug release, realizing precise tumor cell killing. Using Ce6 as a model drug, MIDRS enabled organelle-level photodynamic therapy, triggering innate and adaptive immunity simultaneously. In vivo evaluation showed that MIDRS MT could identify tumor tissue carrying SNVs in mtDNA in unilateral, bilateral, and heterogeneous tumor models, producing an excellent antitumor effect (~82.6%) without affecting normal cells and thus resulting in a stronger systemic antitumor immune response. Additionally, MIDRS was suitable for genotype-specific precision drug release of chemotherapeutic drugs. This strategy holds promise for mutation-specific personalized tumor treatment approaches.
Keyphrases
- drug release
- mitochondrial dna
- copy number
- drug delivery
- immune response
- photodynamic therapy
- induced apoptosis
- drug induced
- stem cells
- squamous cell carcinoma
- machine learning
- cell cycle arrest
- oxidative stress
- dna methylation
- cell proliferation
- cell death
- young adults
- bone marrow
- reactive oxygen species
- cell therapy