Polymer-Based Gene Delivery: A Current Review on the Uptake and Intracellular Trafficking of Polyplexes

Patrick      Midoux; Gilles      Breuzard; Jean   Pierre   Gomez; Chantal      Pichon

Abstract

Lipoplexes and polyplexes, electrostatic complexes between a plasmid DNA and cationic lipids or polymers are chemical systems that are developed for gene delivery. Considerable efforts have been done to delineate the exact knowledge of their entry mechanisms and the intracellular routing of the plasmid DNA that are of major importance for the designing of these gene delivery systems. While the uptake of lipoplexes made with several types of cationic lipids proceeds mainly by the clathrin-dependent pathway, it appears that for polyplexes the uptake pathway is more dependent on the polymer and the cell types. So, after an overview of the current knowledge of different endocytic pathways, we present here a selection of current reports related to the entry mechanisms and intracellular routing of plasmid DNA complexed with select cationic polymers. The review includes the role of glycosaminoglycans, cell polarization and cell cycle in the polyplex uptake and their transfection efficiency. We also report current data showing that the insertion of specific κB motifs in the nucleic acid sequence provides an increase of the plasmid import into the nucleus. This has been demonstrated by fluorescence methods suitable to investigate the intracellular trafficking of pDNA. Overall, it appears that polyplex uptake proceeds both by the clathrin-dependent pathway and a clathrin-independent (cholesterol- dependent) pathway. These two entry mechanisms are not exclusive and can occur simultaneously in the same cell. Both of them lead to cell transfection but polyplexes still need improvements for clinical use.

Keywords: Cationic polymers, polyplexes, gene delivery, non-viral gene transfer, PEI, histidine, confocal microscopy, cellular imaging, endocytosis, nuclear import