Bioreducible Zinc(II)-Coordinative Polyethylenimine with
Low Molecular Weight for Robust Gene Delivery of Primary and Stem Cells
Liu, S (Liu, Shuai)[ 1 ] ; Zhou, DZ (Zhou, Dezhong)[ 1 ] ; Yang, JX (Yang, Jixiang)[ 1 ] ; Zhou, H (Zhou, Hao)[ 2 ] ; Chen, JT (Chen, Jiatong)[ 2 ] ; Guo, TY (Guo, Tianying)[ 1 ]
JOURNAL OF
THE AMERICAN CHEMICAL SOCIETY, 2017, 139(14): 5102-5109
DOI: 10.1021/jacs.6b13337
WOS:000399353800024
Abstract:
To transform common low-molecular-weight (LMW) cationic
polymers, such as polyethylenimine (PEI), to highly efficient gene vectors
would be of great significance but remains challenging. Because LMW cationic
polymers perform far less efficiently than their high-molecular-weight
counterparts, mainly due to weaker nucleic acid encapsulation, herein we report
the design and synthesis of a dipicolylamine-based disulfide-containing
zinc(II) coordinative module (Zn-DDAC), which is used to functionalize LMW PEI
(M-w approximate to 1800 Da) to give a non-viral vector (Zn-PD) with high efficiency
and safety in primary and stem cells. Given its high phosphate binding
affinity, Zn-DDAC can significantly-promote the DNA packaging functionality of
PEI1.8k and improve the cellular uptake of formulated polyplexes, which is
particularly critical for hard-to-transfect cell types. Furthermore, Zn-PD
polymer can be cleaved by glutathione in cytoplasm to facilitate DNA release
post internalization and diminish the cytotoxicity. Consequently, the optimal
Zn-PD mediates 1-2 orders of magnitude higher gluciferase activity than
commercial transfection reagents, Xfect and PEI(25)k, across diverse cell
types, including primary and stem cells. Our findings provide a valuable
insight into the exploitation of LMW cationic polymers for gene delivery and
demonstrate great promise for the development of next-generation non-viral
vectors for clinically viable gene therapy.
