Cell-cycle dependent nuclear gene delivery enhances the effects of E-cadherin against tumor invasion and metastasis

Gene delivery is the process by which foreign DNA is transferred to host cells, released from intracellular vesicles, and transported to the nuclei for transcription. This process is frequently inefficient and difficult to control spatiotemporally. We developed a gene delivery strategy that uses ult...

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Bibliographic Details
Published in:Signal transduction and targeted therapy 2023-05, Vol.8 (1), p.182-182, Article 182
Main Authors: Xie, Liting, Wang, Jieqiong, Song, Liming, Jiang, Tianan, Yan, Fei
Format: Article
Language:English
Subjects:
631/61/201
631/67/322
Acoustics
Cadherins - genetics
Cadherins - metabolism
Cancer Research
Cavitation
Cbfa-1 protein
Cell Biology
Cell cycle
Cell Line, Tumor
Cell Nucleus - genetics
Cell Nucleus - metabolism
Collagenase 3
Cytoplasm
E-cadherin
Gene transfer
Gene Transfer Techniques
Internal Medicine
Intracellular
Medicine
Medicine & Public Health
Metastases
Metastasis
Molecular modelling
Nuclei
Oncology
Pathology
Radiation
Tumor cells
Tumors
Vesicles
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Summary:Gene delivery is the process by which foreign DNA is transferred to host cells, released from intracellular vesicles, and transported to the nuclei for transcription. This process is frequently inefficient and difficult to control spatiotemporally. We developed a gene delivery strategy that uses ultrasound to directly deliver plasmid DNA into nuclei via gas vesicles (GVs)-based intracellular cavitation. pDNA-binding GVs can be taken up by cells and cause intracellular cavitation when exposed to acoustic irradiation and delivering their pDNA payloads into nuclei. Importantly, GVs can remain stable in the cytoplasm in the absence of acoustic irradiation, allowing for temporally controlled nuclear gene delivery. We were able to achieve spatiotemporal control of E-cadherin nuclear gene delivery in this manner, demonstrating its efficacy in tumor invasion and metastasis inhibition. Interestingly, we discovered that nuclear gene delivery of E-cadherin during the G2/M phase of the cell cycle in C6 tumor cells inhibited tumor invasion and metastasis more effectively than during the G1 and S phases. The gene delivery of E-cadherin at the G2/M phase resulted in significantly lower expression of Fam50a, which reduced Fam50a/Runx2 interaction and led to reduced transactivation of MMP13, an important factor for epithelial-mesenchymal transition, as observed in a molecular mechanism assay. Thus, using remote acoustic control of intracellular cavitation of pDNA-GVs, we developed a high spatiotemporally controllable gene delivery strategy and achieved stronger tumor invasion and metastasis inhibition effects by delivering the E-cadherin gene at the G2/M phase.
ISSN:2059-3635
2095-9907
2059-3635
DOI:10.1038/s41392-023-01398-4