Genetic Immunization With In Vivo Dendritic Cell-targeting Liposomal DNA Vaccine Carrier Induces Long-lasting Antitumor Immune Response.

A major limiting factor retarding the clinical success of dendritic cell (DC)-based genetic immunizations (DNA vaccination) is the scarcity of biologically safe and effective carrier systems for targeting the antigen-encoded DNA vaccines to DCs under in vivo settings. Herein, we report on a potent, mannose receptor selective in vivo DC-targeting liposomes of a novel cationic amphiphile with mannose-mimicking shikimoyl head-group. Flow cytometric experiments with cells isolated from draining lymph nodes of mice s.c. immunized with lipoplexes of pGFP plasmid (model DNA vaccine) using anti-CD11c antibody-labeled magnetic beads revealed in vivo DC-targeting properties of the presently described liposomal DNA vaccine carrier. Importantly, s.c. immunizations of mice with electrostatic complex of the in vivo DC-targeting liposome and melanoma antigen-encoded DNA vaccine (p-CMV-MART1) induced long-lasting antimelanoma immune response (100 days post melanoma tumor challenge) with remarkable memory response (more than 6 months after the second tumor challenge). The presently described direct in vivo DC-targeting liposomal DNA vaccine carrier is expected to find future exploitations toward designing effective vaccines for various infectious diseases and cancers.

Examples of Tumor Growth Inhibition Properties of Liposomal Formulations of pH-Sensitive Histidinylated Cationic Amphiphiles.

Herein we report on the unexpected cancer cell selective cytotoxicities of the liposomal formulations of aspartic and glutamic acid backbone-based four novel lipids with endosomal pH-sensitive head-groups and aliphatic n-hexadecyl & n-octadecyl hydrophobic tails. Surprisingly, although the formulations killed cancer cells efficiently, they were significantly less cytotoxic in non-cancerous healthy cells. Importantly, intratumoral administration of the liposomal formulations efficiently inhibited growth of melanoma in a syngeneic C57BL/6J mouse tumor model. Western Blotting experiments with the lysates of liposomes treated cancer cells revealed that liposomes of lipids 1-4 induce apoptosis selectively in cancer cells presumably by releasing cytochrome c from depolarized mitochondria and subsequent activation of caspases 3 & 9, upregulation of Bax and down regulation of Bcl-2. In summary, the present report describes for the first time tumor growth inhibition properties of the liposomal formulations of endosomal pH-sensitive histidinylated cationic lipids under both in vitro and systemic settings.

A long-lasting dendritic cell DNA vaccination system using lysinylated amphiphiles with mannose-mimicking head-groups.

Dendritic cells (DCs) pulsed/transduced with tumor-associated or viral antigens have shown promise in combating cancer and infectious diseases. Despite significant progresses, development of a biologically safe DC-based genetic immunization (DNA vaccination) system capable of providing truly long-lasting protective immunity remains a significant scientific challenge. Here we show that immunization with autologous DCs pre-transfected with electrostatic complexes (lipoplexes) of a plasmid DNA encoding melanoma tumor associated antigen and liposomes of two lysinylated cationic amphiphiles with mannose-mimicking quinic and shikimic acid head-groups provides long-lasting (300 days post tumor challenge) protective immunity with significant memory response (more than six months after the second tumor challenge) in more than 80% immunized mice. The presently described non-viral ex vivo DC-transfection system may be exploited in inducing long-lasting immune response in DC-based genetic immunization.

Cationic amphiphile with shikimic acid headgroup shows more systemic promise than its mannosyl analogue as DNA vaccine carrier in dendritic cell based genetic immunization.

Mannosylated cationic vectors have been previously used for delivering DNA vaccines to antigen presenting cells (APCs) via mannose receptors expressed on the cell surface of APCs. Here we show that cationic amphiphiles containing mannose-mimicking quinic acid and shikimic acid headgroups deliver genes to APCs via mannose receptor. Cationic amphiphile with shikimic acid headgroup was more efficacious than its mannosyl counterpart in combating mouse tumor growth by dendritic cell (the most professional APC) based genetic immunization.