EGFR-homing dsRNA activates cancer-targeted immune response and eliminates disseminated EGFR-overexpressing tumors in mice.

PURPOSE: The cause of most cancer deaths is incurable dissemination of cancer cells into vital organs. Current systemic therapies for disseminated cancers provide limited efficacy and are often accompanied by toxic side effects. We have recently shown that local application of epidermal growth factor receptor (EGFR)-targeted polyinosine-cytosine (polyIC) eradicates preestablished EGFR-overexpressing tumors. Here we show for the first time the high efficiency of systemic application of polyIC/melittin-polyethyleneimine-polyethyleneglycol-EGF (polyIC/MPPE) in combination with human immune cells. EXPERIMENTAL DESIGN: Cancer-targeted activation of immune cells was examined in vitro and in vivo following transfection with polyIC/MPPE. The therapeutic efficiency of the strategy was then examined on disseminated EGFR-overexpressing tumors grown in severe combined immunodeficient (SCID) mice. RESULTS: Intravenous delivery of polyIC/MPPE followed by intraperitoneal injection of peripheral blood mononuclear cells induced the complete cure of SCID mice with preestablished disseminated EGFR-overexpressing tumors, with no adverse toxic effects. The immune cells and the cytokines they produce are localized to the tumor site of the treated animal and contribute decisively to the demise of the tumor cells. The immune system homes to the tumors, due to the chemokines produced by the internalized polyIC. CONCLUSION: The EGFR-homing vector loaded with polyIC can be used to treat and possibly cure patients with disseminated EGFR-overexpressing tumors. The possibility of adopting this strategy to treat other tumors that express a protein capable of ligand induced internalization is discussed.

Induction of apoptosis in murine neuroblastoma by systemic delivery of transferrin-shielded siRNA polyplexes for downregulation of Ran.

The polymer, OEI-HD, based on beta-propionamide-cross-linked oligoethylenimine and its chemical transferrin conjugate were evaluated for siRNA delivery into murine Neuro2A neuroblastoma cells in vitro and in vivo. An 80% silencing of luciferase expression in neuroblastoma cells, stably transfected with a luciferase gene, was obtained using standard OEI-HD polyplexes or transferrin-conjugated shielded OEI-HD polyplexes. The Ras-related nuclear protein Ran was selected as a therapeutically relevant target protein. Systemic delivery of transferrin-conjugated OEI-HD/RAN siRNA formulations (three intravenous applications at 3 days interval) resulted in >80% reduced Ran protein expression, apoptosis, and a reduced tumor growth in Neuro2A tumors of treated mice. The treatment was not associated with signs of acute toxicity or significant changes in weight, hematology parameters, or liver enzymes (AST, ALT, or AP) of mice. All our results demonstrate that OEI-HD/siRNA formulations can knockdown genes in tumor cells in vitro and in vivo in mice in the absence of unspecific toxicity.

DNA polyplexes based on degradable oligoethylenimine-derivatives: combination with EGF receptor targeting and endosomal release functions.

Combination of the degradable polymeric gene carriers OEI-HD-1 and LT- OEI-HD-1 with an EGF targeting conjugate resulted in strongly (up to 900-fold) enhanced polyplex activity in EGF-receptor rich HUH7 hepatocellular carcinoma cells. The targeting ligand effect was DNA dose dependent, could be blocked by competitive receptor binding with unbound EGF ligand, and was not observed in receptor-negative control cells. Measures which enhance intracellular endosomal escape, either photochemically enhanced intracellular release (PCI) or the incorporation of a novel membrane-active melittin analog NMA-3, further enhanced gene transfer activity of EGF/OEI-HD-1 polyplexes.

Melittin analogs with high lytic activity at endosomal pH enhance transfection with purified targeted PEI polyplexes.

Melittin-polyethylenimine (PEI) conjugates have been shown to enhance gene transfer efficiency of polyplexes due to their membrane-destabilizing properties. Inherent lytic activity at neutral pH however also provokes high cytotoxicity due to plasma membrane damage. In order to shift the lytic activity towards the endosomal membrane, several melittin analogs were designed. Acidic modification of melittin by replacing neutral glutamines (Gln-25 and Gln-26) with glutamic acid residues greatly improved the lytic activity of C-terminally linked PEI conjugates at the endosomal pH of 5. This activity correlated well with the gene transfer efficiency of polyplexes in four different cell lines. Melittin-PEI conjugates with high lytic activities at endosomal pH were then incorporated into EGF receptor-targeted and polyethylene glycol-shielded polyplexes. The resulting particles had virus-like dimension (150 nm) with a neutral surface charge and were subsequently purified by size exclusion chromatography to remove unbound toxic PEI conjugate. These purified polyplexes mediated EGF-receptor-specific gene transfer with up to 70-fold higher activity compared to the corresponding PEI polyplexes without melittin.

Stability and release characteristics of poly(D,L-lactide-co-glycolide) encapsulated CaPi-DNA coprecipitation.

The aims of this work were to determine the stability of DNA-calcium-phosphate coprecipitation (CaPi-DNA) against various conditions during double emulsification microencapsulation and assess the release and physicochemical characteristics of poly(D,L-lactide-co-glycolide) (PLGA) microparticles loading CaPi-DNA. CaPi-DNA prepared at pH 6.5 showed a good stability with over 60% CaPi-DNA remained after emulsification, but no more than 40% at pH 8.0. Polyvinyl alcohol (PVA, 1-5%) could make over 80% CaPi-DNA (pH 7.0) preserved after homogenization. The dichloromethane (DCM), mixture of DCM and ethyl acetate, ether and n-hexane (1:1) exhibited neglectable influence on CaPi-DNA under homogenization. PLGA had influenced on CaPi-DNA without any additional stabilizer, in particular, PLGA (75:25, 4%, w/v) demonstrated a profound damage with only about 10% of the original CaPi-DNA remained. PLGA microparticles loading CaPi-DNA were spherical in shape with size range of 2.0-5.0microm, and entrapment efficiency 30-50%. CaPi-DNA was found to increase the stability of pDNA in PLGA microparticles without losing its structure integrity. The release of CaPi-DNA from microparticles showed a low burst release (<7.5%) within 24h and following sustained release process. The amount of cumulated CaPi-DNA release over 30 days was: 17.6% for PLGA (lactide:glycolide=50:50), 27.3% for PLGA (65:35) and 44.8% for PLGA (75:25) microparticles, respectively. The encapsulation of CaPi-DNA in microparticles could significantly protect CaPi-DNA from degradation of nuclease with average over 80% of total DNA recovery. These results suggested that the encapsulation of CaPi-DNA in PLGA microparticles could improve stability of pDNA.

Novel shielded transferrin-polyethylene glycol-polyethylenimine/DNA complexes for systemic tumor-targeted gene transfer.

Tumor-targeting DNA complexes which can readily be generated by the mixing of stable components and freeze-thawed would be very advantageous for their subsequent application as medical products. Complexes were generated by the mixing of plasmid DNA, linear polyethylenimine (PEI22, 22 kDa) as the main DNA condensing agent, PEG-PEI (poly(ethylene glycol)-conjugated PEI) for surface shielding, and Tf-PEG-PEI (transferrin-PEG-PEI) to provide a ligand for receptor-mediated cell uptake. Within the shielding conjugates, PEG chains of varying size (5, 20, or 40 kDa) were conjugated with either linear PEI22 (22 kDa) or branched PEI25 (25 kDa). The three polymer components were mixed together at various ratios with DNA; particle size, surface charge, in vitro transfection activity, and systemic gene delivery to tumors was investigated. In general, increasing the proportion of shielding conjugate in the complex reduced surface charge, particle size, and in vitro transfection efficiency in transferrin receptor-rich K562 cells. The particle size or surface charge of the complexes containing the PEG-PEI conjugate did not significantly change after freeze-thawing, while complexes without the shielding conjugate aggregated. Complexes containing PEG-PEI conjugate efficiently transfected K562 cells after freeze-thawing. Furthermore the systemic application of freeze-thawed complexes exhibited in vivo tumor targeted expression. For complexes containing the luciferase reporter gene the highest expression was found in tumor tissue of mice. An optimum formulation for in vivo application, PEI22/Tf-PEG-PEI/PEI22-PEG5, containing plasmid DNA encoding for the tumor necrosis factor (TNF-alpha), inhibited tumor growth in three different murine tumor models. These new DNA complexes offer simplicity and convenience, with tumor targeting activity in vivo after freeze-thawing.