Efficient gene vector with size changeable and nucleus targeting in cancer therapy.

The nucleus is one of the most important cellular organelles, where gene encode and transcribe at that location. However, nucleus-targeting gene delivery are rare been reported. It is important to develop a high-efficiency nucleus-targeting gene vector that can deliver targeted gene into nucleus directly for destroy of cancer cells. Here, special nucleus-targeting and size changeable deliver system based on TAT-SS-PAMAM-D3 with TAT functional on the surface and disulfide linked between D2 and D3 is designed to perform highly efficient nucleus-targeting gene delivery for effective cancer cell killing in vitro. CLSM observations reveal that more TAT-SS-PAMAM-D3 are enter into the nucleus when compare to SS-PAMAM-D3. The TAT modified vector can also act as gene deliver to reach high gene transfection efficiencies, high apoptosis and low viability in HeLa cells. This TAT functionalized and disulfide linking in the carrier may become a prospective vector for cancer gene treatment and also offered a different strategy for designing a better gene delivery system.

TAT-conjugated chitosan cationic micelle for nuclear-targeted drug and gene co-delivery.

We developed a high-efficiency nucleus-targeted co-delivery vector that delivers genes and drugs directly into the nucleus of cancer cells. The system is based on grafted poly-(N-3-carbobenzyloxy-lysine) (CPCL) with transactivator of transcription (TAT)- chitosan on the surface. It is designed to perform highly efficient nucleus- targeted gene and drug co-delivery. Confocal laser scanning microscopy (CLSM) revealed that more TAT-CPCL entered the nucleus than does CPCL alone. The TAT-modified vector serves as a gene and drug co-delivery mechanism to achieve high gene transfection efficiency, high apoptosis and low viability in HeLa cells. TAT-CPCL may become a vector for cancer gene treatment and a template for designing better co-deliver systems.