Ikramy A. Khalil scite author profile

The mechanism of the arginine-rich peptide-mediated cellular uptake is currently a controversial issue. Several factors, including the type of peptide, the nature of the cargo, and the linker between them, appear to affect uptake. One of the less studied factors, which may affect the uptake mechanism, is the effect of peptide density on the surface of the cargo. Here, we examined the mechanism of cellular uptake and intracellular trafficking of liposomes modified with different densities of the octaarginine (R8) peptide. Liposomes modified with a low R8 density were taken up mainly through clathrin-mediated endocytosis, leading to extensive lysosomal degradation, whereas those modified with a high R8 density were taken up mainly through macropinocytosis and were less subject to lysosomal degradation. Furthermore, the high density R8-liposomes were able to stimulate the macropinocytosis-mediated uptake of other particles. When plasmid DNA was condensed and encapsulated in R8-liposomes, the levels of gene expression were three orders of magnitude higher for the high density liposomes. The enhanced gene expression by the high density R8-liposomes was highly impaired by blocking uptake through macropinocytosis. The different extents of gene expression from different densities of the R8 peptide on the liposomes could be explained principally by the existence of an intracellular trafficking route, but not by the uptake amount, of internalized liposomes. These results show that the density of the R8 peptide on liposomes determines the uptake mechanism and that this is directly linked to intracellular trafficking, resulting in different levels of gene expression. The human immunodeficiency virus TAT2 -derived peptide is a small basic peptide that has been shown to successfully mediate the efficient cellular uptake of a wide variety of cargos, including proteins, peptides, and nucleic acids (1-3). Torchilin et al. (4) recently demonstrated that even certain TAT-linked liposomes with a diameter of 200 nm could be efficiently internalized into a variety of cell lines in intact form. The attachment of TAT directly to the liposome surface without a spacer or the presence of high molecular weight polyethylene glycol spacers abolished liposome internalization, indicating the importance of the direct contact of TAT with the cell surface (4). More recently, other groups reported an enhanced cellular uptake of liposomes when modified with TAT peptide (5, 6). Complexes formed between TAT-liposomes and DNA also showed enhanced transfection in vitro and in vivo (7).Despite the well demonstrated ability of TAT to internalize different cargos, the internalization mechanism of the peptide itself or its cargo remains a controversial issue. According to early studies, none of the classic receptor-, transporter-, or endocytosis-mediated processes seemed to be involved in the uptake of TAT and other similar peptides (8, 9). Direct penetration-and inverted micelle-driven delivery have been suggested as possible internalization mechanisms (...

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Octaarginine- and Octalysine-modified Nanoparticles Have Different Modes of Endosomal Escape

El-Sayed

Khalil

Kogure

et al. 2008

Journal of Biological Chemistry

185

156

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The present study examines the role of surface modification with an octaarginine peptide (R8) in liposomal escape from endocytic vesicles, using octalysine (K8) as a control cationic peptide; the mechanism of endosomal escape of liposomes was also investigated. Gene expression of condensed plasmid DNA encapsulated in R8-modified nanoparticles was more than 1 order of magnitude higher than that of K8-modified nanoparticles, and 2 orders of magnitude higher than gene expression using unmodified nanoparticles. The difference in gene expression could not be attributed to differences in uptake, as R8-and K8-modified liposomes were taken up primarily via macropinocytosis with comparable efficiency. The extent of R8-nanoparticle escape to the cytosol was double that of K8-nanoparticles. Suppression of endosome acidification inhibited R8-nanoparticle endosomal escape, but enhanced that of K8-nanoparticles. Using spectral imaging in live cells, we showed that R8-and K8-liposomes escaped from endocytic vesicles via fusion between the liposomes and the endosomal membrane. R8-liposomes fused efficiently at both acidic and neutral pH, whereas K8-liposomes fused only at neutral pH. Similar behavior was observed during in vitro lipid mixing and calcein-release experiments. Co-incubation of cells with distinctly labeled K8-and R8-modified nanoparticles confirmed a common uptake pathway and different rates of endosomal escape particularly at longer time intervals. Therefore, it was concluded that R8 on the liposome surface stimulates efficient escape from endocytic vesicles via a fusion mechanism that works at both neutral and acidic pH; in contrast, K8 mediates escape mainly at neutral pH.

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Ikramy A. Khalil

Uptake Pathways and Subsequent Intracellular Trafficking in Nonviral Gene Delivery

High Density of Octaarginine Stimulates Macropinocytosis Leading to Efficient Intracellular Trafficking for Gene Expression

Octaarginine- and Octalysine-modified Nanoparticles Have Different Modes of Endosomal Escape

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