Peptide-mediated gene transfer of cationic lipid/plasmid DNA complexes to endothelial cells.

The purpose of this research is to develop ligand-targeted plasmid based gene delivery systems for gene transfer to tumor endothelium. Cell adhesion assays were used to test the peptide inhibition of human endothelial cell adsorption to vitronectin-treated tissue culture plates. A series of RGD containing peptides were tested in linear form and with one and two disulfide bonds. The linear and two disulfide bond peptides yielded similar IC50 (approximately 1 x 10(-7) M). Substitution of two methionines for cysteines yielded a single disulfide bond that increased the IC50 by 10-fold. The single and double disulfide peptides were derivatized to N-succinyl-dioleoylphopsphatidylethanolamine and incorporated into 100 nm liposomes radiolabeled with H-cholesterylhexadecylether. Liposome uptake by human umbilical vein endothelial cells was tested as a function of lipopeptide surface density. Increase in membrane surface density from 5 to 20mol% increased human umbilical derived endothelial cell (HUVEC) uptake of the liposomes for both the single and double disulfide peptides. Liposome uptake by HUVECs was 3-fold greater for the double disulfide compared to the single disulfide. The single and double disulfide lipopeptides were then tested for gene transfer to HUVECs using DOTMA:Cholesterol cationic liposomes. The polyplexes were formed by rapidly mixing plasmid DNA with DOTMA:CHOL liposomes at a 3:1 charge ratio in 2% ethanol, 10% lactose. The ethanol was removed by lyophilization and upon rehydration, the lipoplexes had a mean diameter of approximately 100nm. HUVEC transfection studies showed that increasing the mol% of the single disulfide RGD lipopeptide to 20mol% increased gene transfer by 10-fold. This increase in transfection could be reduced to that obtained in the absence of lipopeptide by co-incubating the HUVECs with a 100-fold excess of the single disulfide RGD peptide, thus demonstrating lipopeptide mediated gene transfer to endothelial cells.

DC-SIGN-specific liposomal targeting and selective intracellular compound delivery to human myeloid dendritic cells: implications for HIV disease.

Myeloid dendritic cells (MyDCs), prime stimulators of antigen-specific immunity, can serve as one of the major reservoirs for human immunodeficiency virus type-1 (HIV-1). Utilizing mature monocyte-derived MyDCs generated with granulocyte/macrophage colony-stimulating factor, interleukin-4, and tumour necrosis factor-alpha as an in vitro model, we here present the first proof of concept for liposomal compound delivery to these cells by specifically addressing CD209, i.e. DC-specific intercellular adhesion molecule 3-grabbing nonintegrin (DC-SIGN), a MyDC-associated C-type lectin implicated in the transmission of HIV-1 to T helper cells. By employing a liposomally entrapped tracer, calcein, we demonstrate by flow cytometry and mathematics a superior targeting efficacy for DC-SIGN, as compared with select other MyDC markers (CD1a, CD4, CD45R0, and CD83). Fluorescence microscopy reveals time-dependent surface binding and intracellular uptake of DC-SIGN-specific liposomes by both immature and mature MyDCs. This pilot study implies that liposomal targeting to CD209 and related C-type lectins may afford therapeutic intracellular drug delivery to MyDCs and other reservoir and nonreservoir cells susceptible to infection with HIV-1.