Abstract
Glycosaminoglycans (GAGs) expressed ubiquitously on the cell surface are known to interact with a variety of ligands to mediate different cellular processes. However, their role in the internalization of cationic gene delivery vectors such as liposomes, polymers, and peptides is still ambiguous and seems to be controlled by multiple factors. In this report, taking peptides as model systems, we show that peptide chemistry is one of the key factors that determine the dependence on cell surface glycosaminoglycans for cellular internalization and gene delivery. Arginine peptides and their complexes with plasmid DNA show efficient uptake and functional gene transfer independent of the cell surface GAGs. On the other hand, lysine peptides and complexes primarily enter through a GAG-dependent pathway. The peptide-DNA complexes also show differential interaction with soluble GAGs. In the presence of exogenous GAGs under certain conditions, arginine peptide-DNA complexes show increased transfection efficiency that is not observed with lysine. This is attributed to a change in the complex nature that ensures better protection of the compacted DNA in the case of arginine complexes, whereas the lysine complexes get destabilized under these conditions. The presence of a GAG coating also ensures better cell association of arginine complexes, resulting in increased uptake. Our results indicate that the role of both the cell surface and exogenous glycosaminoglycans in gene delivery is controlled by the nature of the peptide and its complex with DNA.
Highlights
Research, Government of India (Project NWP35). □S The on-line version of this article contains supplemental Fig. 1. 1 Recipients of fellowships from Department of Biotechnology, Government of India and Council of Scientific and Industrial Research. 2 To whom correspondence should be addressed: Lab 203, Institute of charide units that are sulfated at various positions
Cellular uptake of HIV-1 TAT peptide conjugated to cargo was first surmised to occur in a manner dependent on the presence of heparan sulfate proteoglycans, which was confirmed by impaired uptake on enzymatic or genetic removal of the cell surface GAGs [13, 18]
Arginine and Lysine Homopeptides Show Nearly Similar Transfection Efficiency in the Presence and Absence of Cell Surface Glycosaminoglycans—To explore the role of cell surface GAGs in DNA delivery efficiency, we first studied the efficiency of transfection of plasmid DNA with R16 and K16 peptides in wild type CHO-K1 and the glycosaminoglycan-deficient pgsA745 (mutant with xylosyl transferase deficiency [24] producing Ͻ10% cell surface proteoglycans [8]) cell lines at a charge ratio Z(ϩ/Ϫ) ϭ 10
Summary
The results above indicate that in the case of R16, the cell surface GAGs do not have any effect on the uptake of the bare peptide or its complex with DNA ( they seem to utilize different modes of entry), nor do they affect the transfection efficiency. Arginine- and lysine-based peptide-DNA complexes behave differently in the presence of exogenous GAGs, which reflects in their cellular entry and transfection efficiencies.
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