Arginine-rich peptides, penetratins, as part of a number of cellular and viral proteins, can penetrate across plasma membrane directly, without participation of endocytosis. We show that one of penetratins, the basic domain 47-57 of human immunodeficiency virus, type 1, transcription factor Tat (Tat peptide), is able to interact with plasmid DNA electrostatically. These interactions result in formation of polyelectrolytic complexes at various negative/positive charge ratios of plasmid DNA and Tat peptide. Plasmid DNA is capable of binding to Tat peptide up to 1.7-fold excess of the complex positive charge. The DNA-Tat complexes can be used for delivery of plasmid DNA into mammalian cells. Transfection efficacy of cultured cells by DNA-Tat complexes is stimulated by free Tat peptide, most likely because it protects DNA-Tat complexes from disruption by anionic proteoglycans of cellular surface. Our data strongly argue in favor of the endocytosis-dependent mechanism of DNA-Tat complex uptake by mammalian cells similarly to internalization of complexes of plasmid DNA with other polycationic carriers. Moreover, different cell lines use different endocytosis-mediated pathways for DNA-Tat complex internalization. Intravenous injections to mice of DNA-Tat complexes in comparison with injections of naked DNA showed an inhibitory effect of DNA-Tat complex positive charge on expression of transferred gene. A low level of foreign gene expression in the liver of mice injected intravenously with positively charged DNA-Tat complexes is accounted for by inactivation of DNA-Tat complexes in the bloodstream due to their interactions with serum albumin. These data should be taken into account in an attempt to develop versatile gene delivery systems based on penetratin application for human disease therapy.
This work was devoted to the study of conditions of the formation of DNA/K8 complex and analysis of factors effecting the entry of DNA/K8 complex into mammalian cells in comparison with DNA complexes with arginine-rich fragment (47-57) of human immunodeficiency virus (type 1) transcription factor Tat (Tat peptide). The stoichiometry of positively charged DNA/K8 complexes has been studied for the first time. Non-cooperative character of DNA-K8 interaction was revealed. It has been shown that along with the positive charge of such complexes, the presence of an excess of free K8 peptide in the culture medium is a necessary condition for maximal efficiency of cell transfection with DNA/K8 complexes. A stimulatory effect of free K8 peptide on the efficiency of mammalian cell transfection by DNA/K8 complexes is likely to be mediated by the interactions of cationic peptide K8 with negatively charged proteoglycans on the cell surface, which leads to protection of DNA/K8 complexes from disruption by cellular heparan sulfates. However, the protective role of free cationic peptides depends not only on their positive charge, but also on the primary structure of the peptide. In contrast with the results obtained for DNA complexes with molecular conjugates based on poly-L-lysine, the aggregation of DNA/K8 complexes leads to a significant increase in the expression of transferred gene.
With the goal of developing non-viral techniques for exogenous gene delivery into mammalian cells, we have studied receptor-mediated gene transfer using complexes of plasmid DNA and galactosylated poly-L-lysine, poly(L-Lys)Gal. To evaluate the optimal parameters for efficient gene transfer into human hepatoma HepG2 cells by the DNA-poly(L-Lys)Gal complexes, the bacterial reporter genes lacZ and cat were used. Examination of the reporter gene expression level showed that the efficiency of DNA delivery into the cells depends on the structure of DNA--poly(L-Lys)Gal complexes formed at various ionic strength values. The efficiency of DNA transfer into the cells also depends on DNA/poly(L-Lys)Gal molar ratio in the complexes. Plasmid vector carrying human apolipoprotein A-I (apoA-I) gene was injected as its complex with poly(L-Lys)Gal into rat tail vein. Some level of ApoA-I was detected in the serum of the injected rats. Also, the human apoA-I-containing plasmid was found to be captured specifically by the rat liver cells and transported into the cell nuclei, where it can persist as an episome-like structure for at least a week. After repeated injections of DNA--poly(L-Lys)Gal complexes, the level of human ApoA-I in rat serum increases, probably, due to accumulation of functional human apoA-I gene in the liver cell nuclei. The data seem to be useful for the development of non-viral approaches to gene therapy of cardiovascular diseases.
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