Dhananjay Jere

Galactosylated poly(ethylene glycol)-chitosan-graft-polyethylenimine as a gene carrier for hepatocyte-targeting

Chitosan and chitosan derivatives have been proposed as alternative and biocompatible cationic polymers for non-viral gene delivery. However, the low transfection efficiency and low specificity of chitosan is an aspect of this approach that must be addressed prior to any clinical applications. In the present study a chitosan derivative, galactosylated poly(ethylene glycol)-chitosan-graft-polyethylenimine (Gal-PEG-CHI-g-PEI), was investigated as a potential hepatocyte-targeting gene carrier. The composition of Gal-PEG-CHI-g-PEI was characterized using (1)H nuclear magnetic resonance ((1)H NMR), and the particle size and zeta potential of Gal-PEG-CHI-g-PEI/DNA complexes were measured using dynamic light scattering (DLS). The Gal-PEG-CHI-g-PEI exhibited lower cytotoxicity compared to PEI 25K as a control. Likewise, Gal-PEG-CHI-g-PEI/DNA complexes showed good hepatocyte specificity. Furthermore, Gal-PEG-CHI-g-PEI/DNA complexes transfected liver cells more effectively than PEI 25K in vivo after intravenous (i.v.) administration. Together, these results suggest that Gal-PEG-CHI-g-PEI, which has improved transfection efficiency and hepatocyte specificity both in vitro and in vivo, may be useful for gene therapy.

The suppression of lung tumorigenesis by aerosol-delivered folate-chitosan-graft-polyethylenimine/Akt1 shRNA complexes through the Akt signaling pathway

RNA interference (RNAi) represents a promising new approach to the inhibition of gene expression in vitro and in vivo, and has therapeutic potential for human diseases. Efficient delivery of small interfering RNA (siRNA) or small hairpin RNA (shRNA) is a critical concern in RNAi studies. Here we report the development of a new polymeric gene carrier for cancer cell-targeting, designed to enhance the intracellular delivery of shRNA and reduce cytotoxicity. Folate-chitosan-graft-polyethylenimine (FC-g-PEI) copolymer was prepared by an imine reaction between periodate-oxidized folate-chitosan (FC) and low molecular weight polyethylenimine (PEI). FC-g-PEI copolymer was investigated as a potential cancer cell-targeting gene carrier. The composition of FC-g-PEI was characterized using (1)H nuclear magnetic resonance ((1)H NMR), and particle size and zeta potential of FC-g-PEI/shRNA complexes were measured using dynamic light scattering (DLS). FC-g-PEI showed good shRNA condensation ability and high protection of shRNA from nuclease attack. It also exhibited lower cytotoxicity compared to PEI 25K control, and showed good cancer cell-targeting ability. Furthermore, aerosol delivery of FC-g-PEI/Akt1 shRNA complexes suppressed lung tumorigenesis in a urethane-induced lung cancer model mouse through the Akt signaling pathway. Together, these results suggest that FC-g-PEI may be useful for shRNA-based gene therapy.

Poly(β-amino ester) as a carrier for si/shRNA delivery in lung cancer cells

Efficient delivery of small interfering RNA (siRNA) or small hairpin RNA (shRNA) is a critical concern in RNA interference (RNAi) studies. In the present study, we evaluated biodegradable poly(beta-amino ester) (PAE) carrier composed of low molecular weight polyethylenimine and poly(ethylene glycol) for si/shRNA delivery in lung cancer cells. PAE carrier successfully delivered EGFP (enhanced green fluorescence protein) siRNA (siGFP) and silenced EGFP expression. The silencing achieved with PAE carrier was found to be nearly 1.5 times superior and safer than standard PEI25K. Also, our PAE carrier exhibited superior Akt1 shRNA delivery (shAkt) and thereby silenced oncoprotein Akt1 efficiently. PAE-shAkt mediated Akt1 knock-down hindered cancer cell growth in Akt1 specific manner. Superior shAkt delivery and low cytotoxicity of PAE carrier promoted Akt1 knock-down specific apoptosis, while low delivery efficiency and high cytotoxicity of PEI25K carrier mainly exhibited undesirable necrosis. Moreover, basic cancer properties like cell proliferation, malignancy and metastasis were reduced more efficiently using PAE-shAkt system. These findings demonstrated the potential of PAE as an alternative to PEI25K in si/shRNA-based RNAi studies.

Degradable polyethylenimines as DNA and small interfering RNA carriers

Gene therapy is a powerful approach in the treatment of a wide range of both inherited and acquired diseases. Nonviral delivery systems have been proposed as safer alternatives to viral vectors because they avoid the inherent immunogenicity and production problems that are seen when viral systems are used. Many cationic polymers, including high-molecular-weight polyethylenimine (PEI) have been widely studied as gene-delivery carriers, both, in vitro and in vivo. However, interest has recently developed in degradable polymeric systems. The advantage of degradable polymer is its low in-vivo cytotoxicity, which is a result of its easy elimination from the cells and body. Degradable polymer also enhances transfection of DNA or small interfering RNA (siRNA) for efficient gene expression or silencing, respectively. This review paper summarizes and discusses the recent advances with degradable PEIs, such as cross-linked and grafted PEIs for DNA and siRNA delivery.

Chitosan-graft-polyethylenimine for Akt1 siRNA delivery to lung cancer cells

Efficient delivery of small interfering RNA (siRNA) remains a challenging task in RNA interference (RNAi) studies. In this study, we used chitosan-graft-polyethylenimine (CHI-g-PEI) copolymer composed of chitosan and low molecular weight polyethylenimine (PEI) for the delivery of siRNA. The CHI-g-PEI carrier formed stable complexes with siRNA with compact spherical morphology. CHI-g-PEI delivered EGFP siRNA (siGFP) silenced EGFP expression nearly 2.5 folds higher than PEI25K at 50 pM siGFP concentration. Cell viability was found to be 2 folds high with CHI-g-PEI carrier than PEI25K. Also, our CHI-g-PEI carrier efficiently delivered Akt1 siRNA (siAkt) and thereby silenced onco-protein Akt1. Silencing of this crucial cell survival protein significantly reduced the lung cancer cell survival and proliferation. Additionally, Akt1 protein knock-down decreased A549 cell malignancy and metastasis. These findings suggest that the CHI-g-PEI carrier efficiently and safely delivered siRNA. Moreover, CHI-g-PEI mediated Akt1 siRNA delivery may emerge as a viable approach for lung cancer treatment.

Poly(ester amine)-mediated, Aerosol-delivered Akt1 Small Interfering RNA Suppresses Lung Tumorigenesis

RATIONALE The low efficiency of conventional therapies in achieving long-term survival of patients with lung cancer calls for the development of novel therapeutic options. Recent advances in aerosol-mediated gene delivery have provided the possibility of an alternative for the safe and effective treatment of lung cancer. OBJECTIVES To demonstrate the feasibility and emphasize the importance of noninvasive aerosol delivery of Akt1 small interfering RNA (siRNA) as an effective and selective option for lung cancer treatment. METHODS Nanosized poly(ester amine) polymer was synthesized and used as a gene carrier. An aerosol of poly(ester amine)/Akt1 siRNA complex was delivered into K-ras(LA1) and urethane-induced lung cancer models through a nose-only inhalation system. The effects of Akt1 siRNA on lung cancer progression and Akt-related signals were evaluated. MEASUREMENTS AND MAIN RESULTS The aerosol-delivered Akt1 siRNA suppressed lung tumor progression significantly through inhibiting Akt-related signals and cell cycle. CONCLUSIONS The use of poly(ester amine) serves as an effective carrier, and aerosol delivery of Akt1 siRNA may be a promising approach for lung cancer treatment and prevention.

Biodegradable poly(ester amine) based on glycerol dimethacrylate and polyethylenimine as a gene carrier

Polyethylenimine (PEI) vectors are widely used in gene delivery because of their high transfection efficiency owing to a unique proton sponge effect. An increase in molecular weight increases transfection efficiency, but simultaneously results in increased toxicity. Therefore, the design and synthesis of new degradable gene delivery carriers having high transfection efficiencies and reduced cytotoxicity are necessary.

Akt1 silencing efficiencies in lung cancer cells by sh/si/ssiRNA transfection using a reductable polyspermine carrier.

Efforts directed in ameliorating silencing studies with shRNA, siRNA and ssiRNA (siRNA with sticky overhangs) are faltered mainly due to the lack of efficient carrier system. In the present study, we developed reductable polyspermine (RPS) carrier composed of multiple spermine units with disulfide linkages for gene expression and silencing studies. In gene expression studies, EGFP expression was found to be almost 4 folds higher and 20 folds safer with RPS carrier than with PEI25K. Moreover, on systemic administration, RPS exhibited significantly high EGFP expression in mice lungs. Similarly in gene silencing studies, EGFP silencing achieved was nearly 1.5 times superior with RPS carrier than PEI25K. Also, RPS delivered Akt1 shRNA (shAkt), siRNA (siAkt) and ssiRNA (ssiAkt) efficiently silenced oncoprotein Akt1 and thereby decreased A549 cell survival. The degrees of cell survival, proliferation and metastasis were differed with the nature of siRNA treatment. Further study at different time intervals revealed that ssiAkt treatment, although superior to sh/siAkt, was highly transient while, shAkt treatment was uniform and prolong. These finding demonstrate the potential use of RPS carrier in gene expression and silencing studies, and significance of the nature of siRNA employed in cancer study.

The therapeutic efficiency of FP-PEA/TAM67 gene complexes via folate receptor-mediated endocytosis in a xenograft mice model

To circumvent carrier related obstacles, we developed a biodegradable, folate conjugated poly (ester amine) (FP-PEA) that mediates high level folate receptor (FR) mediated endocytosis in vitro as well as in vivo. We report the efficacy of a therapeutic strategy that combines the potency of FP-PEA based on polycaprolactone (PCL) and low molecular weight polyethylenimine (LMW-PEI) with the tumor targeting potential of receptor mediated endocytosis. When tested on cells in culture, FP-PEA was found to retain high affinity for FR-positive cells compared with PEA without folate moiety (P-PEA). The FR specific activity of FP-PEA was drastically decreased in the presence of an excess free folic acid and very less significant transfection was detected against FR-negative cells. FP-PEA showed marked anti-tumor activity against FR-positive human KB tumors in nude mice with no evidence of toxicity during and after therapy using TAM67 gene. Furthermore, the therapeutic effect occurred in the apparent absence of weight loss or noticeable tumor apoptosis. In contrast, no significant anti-tumor activity was observed in P-PEA treated mice which were co dosed with an excess of FR, thus demonstrating the target specific gene delivery. Furthermore, anti-tumor activity with PEA without folic acid moiety (P-PEA) proved not to be effective against xenograft mice model with KB cells when administered at the same dose to that of FP-PEA. Taken together, these results indicate that FP-PEA is highly effective gene carrier capable of producing therapeutic benefit in xenograft mice model without any sign of toxicity.

Bioreducible polymers for efficient gene and siRNA delivery

Bioreducible disulfide linkage-employing drug conjugate has already been approved for drug delivery application, and also has shown immense potential in gene and siRNA transfection. This paper will focus on the recent developments in bioreducible polymeric systems for gene and siRNA delivery application, and will discuss the advantages and challenges associated with reducible polymeric carriers.