Efficiency of drug and gene delivery via nonviral vehicles is contingent on proper cellular uptake and intracellular release. Further, various cargos, such as nucleases for gene editing or inhibitors for endosomal receptors, require transport to specific compartments of the cell. Hence, characterization of cellular uptake and endocytic pathways is crucial for the optimization of any nanoparticle-mediated intracellular delivery system. Previous work on endocytic pathways looks at the effect of various pathway inhibitors on the uptake efficiency of nanoparticles carrying fluorescently-labeled cargo. While this helps attribute particle uptake to specific pathways like caveolae-mediated or clathrin-mediated endocytosis, this does not provide a holistic picture of the delivery process. Here, we provide a general protocol that combines systematic studies of inhibitor effects on efficiency with quantification of particle-induced cell membrane permeability. By applying this methodology to a nucleic acid delivery system, for example a helical polypeptide-based nanoparticle for plasmid and guide RNA delivery, we gain understanding of the endocytic mechanisms and cell uptake for intelligent design of intracellular delivery.
Keywords: Cell uptake; Cell-penetrating peptide; Endocytosis; Gene delivery; Gene editing; Intracellular trafficking; Macropinocytosis; Uptake mechanisms.
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