Core-Shell Nanosystems for Self-Activated Drug-Gene Combinations against Triple-Negative Breast Cancer.
Peng LiuXuanjun LiuYan ChengShenghui ZhongXinyi ShiShengfeng WangMiao LiuJinsong DingWenhu ZhouPublished in: ACS applied materials & interfaces (2020)
The combination of gene therapy with chemotherapeutics provides an efficacious strategy for enhanced tumor therapy. RNA-cleaving DNAzyme has been recognized as a promising gene-silencing tool, while its combination with chemotherapeutic drugs has been limited by the lack of an effective codelivery system to allow sufficient intracellular DNAzyme activation, which requires specific metal ions as a cofactor. Here, a self-activatable DNAzyme/drug core-shell codelivery system is fabricated to combat triple-negative breast cancer (TNBC). The hydrophobic chemotherapeutic, rapamycin (RAP), is self-assembled into the pure drug nanocore, and the metal-organic framework (MOF) shell based on coordination between Mn2+ and tannic acid (TA) is coated on the surface to coload an autophagy-inhibiting DNAzyme. The nanosystem efficiently delivers the payloads into tumor cells, and upon endocytosis, the MOF shell is disintegrated to release the therapeutics in response to an acidic endo/lysosome environment and intracellular glutathione (GSH). Notably, the coreleased Mn2+ serves as the cofactor of DNAzyme for effective self-activation, which suppresses the expression of Beclin 1 protein, the key initiator of autophagy, resulting in a significantly strengthened antitumor effect of RAP. Using tumor-bearing mouse models, the nanosystem could passively accumulate into the tumor tissue, impose potent gene-silencing efficacy, and thus sensitize chemotherapy to inhibit tumor growth upon intravenous administration, providing opportunities for combined gene-drug TNBC therapy.
Keyphrases
- metal organic framework
- living cells
- fluorescent probe
- signaling pathway
- gene therapy
- label free
- cell death
- oxidative stress
- copy number
- endoplasmic reticulum stress
- poor prognosis
- emergency department
- long non coding rna
- high dose
- reactive oxygen species
- gene expression
- ionic liquid
- single molecule
- small molecule
- mesenchymal stem cells
- squamous cell carcinoma
- binding protein
- locally advanced
- cell therapy
- transcription factor
- fluorescence imaging
- nucleic acid