Water-soluble lipopolymer as an efficient carrier for gene delivery to myocardium

Water-soluble lipopolymer (WSLP), which consisted of polyethylenimine (PEI, 1800 Da) and cholesterol, was characterized as a gene carrier to smooth muscle cells and myocardium. Acid-base titration showed that WSLP had a proton-buffering effect. The size of WSLP/plasmid DNA (pDNA) complex was around 70 nm. WSLP/pDNA complex was transfected to A7R5 cells, a smooth muscle cell line. WSLP showed the highest transfection at a 40/1 N/P ratio. WSLP has higher transfection efficiency than PEI (1800 and 25 000 Da), SuperFect, and lipofectamine. In addition, WSLP has less cytotoxicity than PEI (25 000 Da), SuperFect, and lipofectamine. Since WSLP has cholesterol moiety, it may utilize cellular cholesterol uptake pathway, in which low-density lipoprotein (LDL) is involved. An inhibition study with free cholesterol or low-density lipoprotein (LDL) showed that transfection was inhibited by cholesterol or LDL, suggesting that WSLP/pDNA complex is transfected to the cells through the cholesterol uptake pathway. To evaluate the transfection efficiency to myocardium, WSLP/pDNA complex was injected into the rabbit myocardium. WSLP showed higher transfection than PEI and naked pDNA. WSLP expressed the transgene for more than 2 weeks. In conclusion, WSLP is an efficient carrier for local gene transfection to myocardium, and useful in in vivo gene therapy.     

Characterization and evaluation of the efficacy of cationic complex mediated plasmid DNA delivery in human embryonic palatal mesenchyme cells

The purpose of this study was to develop and test a non‐viral gene delivery system that can be employed to deliver genes of interest into a pre‐osteoblastic cell line. Human embryonic palatal mesenchymal (HEPM 1486) cells were transfected with vector‐plasmid DNA (pDNA) complexes. We explored calcium phosphate and polyethylenimine (PEI) as non‐viral vectors and compared their respective in vitro transfection efficacies. Plasmid DNA encoding luciferase protein (LUC) was complexed with PEI (with differing N:P ratios) and calcium phosphate (with differing Ca:P ratios), using established protocols. The complexes prepared were then characterized for size and surface charge, using a Malvern Zetasizer Nano‐ZS. The transfection efficiency and cytotoxicity of the prepared complexes were evaluated in HEPM cells. The PEI–pDNA complexes over the whole range of N:P ratios were found to be < 160 nm in size, while the calcium phosphate–pDNA complexes were relatively bigger. The PEI–pDNA complexes prepared at a N:P ratio of 10 were found to have maximum transfection efficiency at 4 h of treatment, with minimal cytotoxicity. The highest transfection efficiency obtained with calcium phosphate–pDNA complexes (Ca:P 200) was nearly 12‐fold lower than that obtained with PEI–pDNA complexes (N:P 10). Following this, transgene expression in the HEPM cells treated with complexes prepared at a N:P ratio of 10 was further examined, using pDNA coding for enhanced green fluorescent protein (EGFP‐N1) or therapeutically relevant platelet‐derived growth factor B (PDGF‐B). In conclusion, PEI was a more effective vector for delivering genes of interest to pre‐osteoblasts than calcium phosphate. Copyright © 2014 John Wiley & Sons, Ltd.     

Chitosan-graft-polyethylenimine as a gene carrier.

Chitosans have been proposed as biocompatible alternative cationic polymers that are suitable for non-viral delivery. However, the transfection efficiency of chitosan-DNA nanoparticles is still very low. To improve transfection efficiency, we prepared chitosan-graft-polyethylenimine (CHI-g-PEI) copolymer by an imine reaction between periodate-oxidized chitosan and polyethylenimine (PEI). The molecular weight and composition of the CHI-g-PEI copolymer were characterized, using multi-angle laser scattering (GPC-MALS) and (1)H nuclear magnetic resonance ((1)H NMR), respectively. The copolymer was complexed with plasmid DNA (pDNA) in various copolymer/DNA (N/P) charge ratios, and the complex was characterized. CHI-g-PEI showed good DNA binding ability and high protection of DNA from nuclease attack. Also, with an increase in charge ratio, the sizes of the CHI-g-PEI/DNA complex showed a tendency to decrease, whereas the zeta potential of the complex showed an increase. The CHI-g-PEI copolymer had low cytotoxicity, compared to PEI 25K from cytotoxicity assays. At high N/P ratios, the CHI-g-PEI/DNA complex showed higher transfection efficiency than PEI 25K in HeLa, 293T and HepG2 cell lines. Our results indicate that the CHI-g-PEI copolymer has potential as a gene carrier in vitro.     

Controlled release of cell-permeable gene complex from poly(L-lactide) scaffold for enhanced stem cell tissue engineering

The use of tissue engineering to deliver genes to stem cells has been impeded by low transfection efficiency of the inserted gene and poor retention at the target site. Herein, we describe the use of non-viral gene transfer by cell-permeable peptide (CPP) to increase the transfection efficiency. The combination of this technique with the use of a controlled release concept using a poly (l-lactide) scaffold allowed for prolonged uptake in stem cells. High transfection efficiency was obtained using a human-derived arginine-rich peptide denoted as Hph-1 (YARVRRRGPRR). The formation of complex between pDNA and Hph-1 was monitored using gel retardation tests to measure size and zeta potential. Complex formation was further assessed using a DNase I protection assay. A sustained gene delivery system was developed using a fibrous 3-D scaffold coated with pDNA/Hph-1 complexes. Transfection efficiency and the mean fluorescence intensity of human adipose-derived stem cells (hASCs) on the sustained delivery scaffold were compared to those of cells transfected via bolus delivery. Plasmid DNA completely bound Hph-1 at a negative-to-positive (N/P) charge ratio of 10. After complex formation, Hph-1 appeared to effectively protect pDNA against DNase I attack and exhibited cytotoxicity markedly lower than that of the pDNA/PEI complex. Plasmid DNA/Hph-1 complexes were released from the scaffolds over 14 days and were successfully transfected hASCs seeded on the scaffolds. Flow cytometry revealed that the transfection efficiency in hASCs treated with pDNA/Hph-1 complex was approximately 5-fold higher than that in cells transfected using Lipofectamine. The sustained delivery system showed a significantly higher transfection efficiency and remained able to transfect cells for a longer period of time than bolus delivery. These results suggest that cell-scaffold-based tissue regeneration can be further improved by transduction concept using CPP and controlled release using polymeric scaffold.     

Degradable polyethylenimine-alt-poly(ethylene glycol) copolymers as novel gene carriers.

An ideal gene carrier requires both safety and transfection efficiency. Polyethylenimine (PEI) is a well-known cationic polymer, which has high transfection efficiency owing to its buffering capacity. But it has been reported that PEI is cytotoxic in many cell lines and non-degradable. In this study, we synthesized degradable PEI-alt-poly(ethylene glycol) (PEG) copolymers using Michael-type addition reactions as a new gene carrier and characterized them. These copolymers were complexed with plasmid DNA and the resulting complexes were characterized by dynamic light scattering, gel retardation and atomic force microscopy to determine particle sizes, complex formation and complex shape, respectively. Cytotoxicity and transfection efficiency of the copolymers were also checked in cultured HeLa human cervix epithelial carcinoma cells, HepG2 human hepatoblastoma cell line and MG63 human osteosarcoma cells. PEG to PEI ratio in the copolymers was near 1 and the molecular weight of the copolymer ranged from around 8000 to 12,900. These copolymers degraded rapidly at 37 degrees C in 0.1 M phosphate buffered saline (PBS, pH 7.4). The complete copolymer/DNA complex was formed at an N/P ratio of 12, producing a complex resistant to DNase I. Particle sizes decreased with increasing N/P ratio and PEG molecular weight, exhibiting a minimum value of 75 nm at an N/P ratio of 45 with PEI-alt-PEG (700). Cytotoxicity study showed that copolymers exhibited no cytotoxic effects on cells even at high copolymer concentration. Also, transfection efficiency was influenced by PEG molecular weight and, in case of PEI-alt-PEG (258), the transfection efficiency was higher than that for PEI 25 K in HepG2 and MG63, whereas it was lower than that for PEI 25K in HeLa cells.     

Human serum albumin-polyethylenimine nanoparticles for gene delivery.

Nanoparticles consisting of DNA, human serum albumin (HSA) and polyethylenimine (PEI) were formed and tested for transfection efficiency in vitro with the aim of generating a nonviral gene delivery vehicle. HSA-PEI-DNA nanoparticles containing the pGL3 vector coding for luciferase as reporter gene were formed by charge neutralization. The particles were characterized by gel retardation assay, dynamic light scattering (size) and electrophoretic mobility measurements (charge). Stability was determined by spectrophotometric analysis and transfection efficiency was evaluated in cell culture using human embryonic epithelial kidney 293 cells. HSA-PEI-DNA nanoparticles were prepared by co-encapsulation of PEI as a lysosomotropic agent at varying nitrogen to phosphate (N/P) ratios. An optimum transfection efficiency was achieved when the particles were prepared at N/P ratios between 4.8 and 8.4. Furthermore, they displayed a low cytotoxicity when tested in cell culture. Our results show that HSA-PEI-DNA nanoparticles are a versatile carrier for DNA that may be suitable for i.v. administration.     

Galactosylated polyethylenimine-graft-poly(vinyl pyrrolidone) as a hepatocyte-targeting gene carrier.

Polyethylenimine (PEI) has been used for the gene delivery system in vitro and in vivo since it has high transfection efficiency owing to proton buffer capacity. However, the use of PEI for gene delivery is limited due to cytotoxicity, non-specificity and unnecessary interaction with serum components. To overcome cytotoxicity and non-specificity, PEI was coupled with poly(vinyl pyrrolidone) (PVP) as the hydrophilic group to reduce cytotoxicity and lactose bearing galactose group for hepatocyte targeting. The galactosylated-PEI-graft-PVP (GPP) was complexed with DNA, and GPP/DNA complexes were characterized. GPP showed good DNA binding ability, high protection of DNA from nuclease attack. The sizes of DNA complexes show tendency to decrease with an increase of charge ratio and had a minimum value around 59 nm at the charge ratio of 40 for the GPP-1/DNA complex (PVP content: 4.1 mol%). The GPP showed low cytotoxicity. And GPP/DNA complexes were mediated by asialoglycoprotein receptors (ASGP-R)-mediated endocytosis. Also, the transfection efficiency of GPP-1/DNA complex at charge ratio of 40 in the HepG2 was higher than that of PEI/DNA one.     

Galactosylated chitosan-graft-polyethylenimine as a gene carrier for hepatocyte targeting

Chitosans have been proposed as alternative, biocompatible cationic polymers for nonviral gene delivery. However, the low transfection efficiency and low specificity of chitosan need to be addressed before clinical application. We prepared galactosylated chitosan-graft-polyethylenimine (GC-g-PEI) copolymer by an imine reaction between periodate-oxidized GC and low-molecular-weight PEI. The molecular weight and composition were characterized using gel permeation chromatography column with multi-angle laser scattering and (1)H nuclear magnetic resonance, respectively. The copolymer was complexed with plasmid DNA in various copolymer/DNA (N/P) charge ratios, and the complexes were characterized. GC-g-PEI showed good DNA-binding ability and superior protection of DNA from nuclease attack and had low cytotoxicity compared to PEI 25K. GC-g-PEI/DNA complexes showed higher transfection efficiency than PEI 25K in both HepG2 and HeLa cell lines. Transfection efficiency into HepG2, which has asialoglycoprotein receptors, was higher than that into HeLa, which does not. GC-g-PEI/DNA complexes also transfected liver cells in vivo after intraperitoneal (i.p.) administration more effectively than PEI 25K. These results suggest that GC-g-PEI can be used in gene therapy to improve transfection efficiency and hepatocyte specificity in vitro and in vivo.     

Galactosylated ternary DNA/polyphosphoramidate nanoparticles mediate high gene transfection efficiency in hepatocytes.

Galactosylated polyphosphoramidates (Gal-PPAs) with different ligand substitution degrees (6.5%, 12.5% and 21.8%, respectively) were synthesized and evaluated as hepatocyte-targeted gene carriers. The in vitro cytotoxicity of Gal-PPA decreased significantly with an increase in galactose substitution degree. The affinity of Gal-PPA/DNA nanoparticles to galactose-recognizing lectin increased with galactose substitution degree. However, decreased transfection efficiency was observed for these galactosylated PPAs in HepG2 cells. Based on the results of gel retardation and polyanion competition assays, we hypothesized that the reduced transfection efficiency of Gal-PPA/DNA nanoparticles was due to their decreased DNA-binding capacity and decreased particle stability. We therefore prepared nanoparticles by precondensing DNA with PPA at a charge ratio of 0.5, yielding nanoparticles with negative surface charge, followed by coating with Gal-PPA, resulting in a Gal-PPA/ DNA/PPA ternary complex. Such a ternary nanoparticle formulation led to significant size reduction in comparison with binary nanoparticles, particularly at low N/P ratios (2 to 5). In HepG2 cells and primary rat hepatocytes, and at low N/P ratios (2 to 5), transfection efficiency mediated by ternary nanoparticles prepared with 6.5% Gal-PPA was 6-7200 times higher than PPA-DPA/DNA nanoparticles. Transgene expression increased slightly at higher N/P ratios in HepG2 cells and reached a plateau at N/P ratios between 5 and 10 for primary rat hepatocytes. Such an enhancement effect was not observed in HeLa cells that lack of asialoglycoprotein receptor (ASGPR). Nevertheless, transfection efficiency of ternary particles decreased dramatically, presumably due to the decreased DNA binding capacity and particle stability, as PPA galactosylation degree increased. This highlights the importance of optimizing ligand conjugation degree for PPA gene carrier.     

Polyethylenimine with acid-labile linkages as a biodegradable gene carrier.

Polyethylenimine (PEI) is a gene carrier with high transfection efficiency. However, PEI has high cytotoxicity, which depends on its molecular weight. To reduce the cytotoxicity, degradable PEIs with acid-labile imine linkers were synthesized with low molecular weight PEI1.8K (1.8 kDa) and glutadialdehyde. The molecular weights of the synthesized acid-labile PEIs were 23.7 and 13 kDa, respectively. The half-life of the acid-labile PEI was 1.1 h at pH 4.5 and 118 h at pH 7.4, suggesting that the acid-labile PEI may be rapidly degraded into nontoxic low molecular weight PEI in acidic endosome. In a gel retardation assay, plasmid DNA (pDNA) was completely retarded at a 3:1 N/P (nitrogen of polymer/phosphate of DNA) ratio. The zeta potential of the polyplexes was in the range of 46.1 to 50.9 mV and the particle size was in the range of 131.8 to 164.6 nm. In vitro transfection assay showed that the transfection efficiency of the acid-labile PEIs was comparable to that of PEI25K. In toxicity assay, the acid-labile PEI was much less toxic than PEI25K, due to the degradation of acid-labile linkage. Therefore, the acid-labile PEIs may be useful for the development of a nontoxic polymeric gene carrier.     

Characterization of a novel diolein-based LPDII vector for gene delivery.

LPDII vectors are non-viral vehicles for gene delivery comprised of polycation-condensed plasmid DNA (polyplexes) complexed with anionic pH-sensitive liposomes. Here, we describe a novel LPDII formulation containing polyethylenimine (PEI) polyplexes complexed with anionic pH-sensitive liposomes composed of diolein/cholesteryl hemisuccinate (CHEMS) (6:4 mol/mol). The pH-sensitivity of diolein/CHEMS liposomes was evaluated through quantitative fluorescence measurements of calcein release and particle size analysis. The results indicated that diolein/CHEMS liposomes are stable at physiological pH, but undergo rapid aggregation and fluorescence dequenching at pH values < or =5.0. Using a luciferase reporter gene, in vitro transfection of KB oral cancer cells showed that the transfection efficiency of LPDII vectors was superior to other well-characterized polyplexes and lipoplexes. Results further showed that gene delivery using diolein-containing LPDII vectors was dependent on the PEI nitrogen/DNA phosphate (N/P) ratio, the lipid/DNA weight ratio and the cell line being transfected. Replacing PEI with poly-L-lysine as the DNA condensing agent resulted in only a moderate reduction in transfection activity. Moreover, in contrast to LPDII formulations incorporating dioleoylphosphatidylethanolamine (DOPE), the transfection efficiency of diolein-based LPDII vectors was sustained in media containing up to 50% fetal bovine serum. Since diolein-based LPDII vectors mediate efficient gene transfer and retain their transfection activity in the presence of serum, diolein may be a promising alternative to DOPE for the construction of non-viral vectors for in vivo gene delivery.     

Biodegradable poly(ethylenimine) for plasmid DNA delivery

Poly(ethylenimine) (PEI) has been known as an efficient gene carrier with the highest cationic charge potential. High transfection efficiency of PEI, along with its cytotoxicity, strongly depends on the molecular weight. Synthesis of cationic copolymers derived from the low molecular weight of PEI and hydrophilic poly(ethylene glycol) (PEG), which are water soluble and degradable under physiological conditions, was investigated for plasmid delivery. Hydrophilic PEG is expected to reduce the toxicity of the copolymer, improve the poor solubility of the PEI and DNA complexes, and help to introduce degradable bonds by reaction with the primary amines in the PEI. Considering the dependence of transfection efficiency and cytotoxicity on the molecular weight of the PEI, high transfection efficiency is expected from an increased molecular weight of the copolymer and low cytotoxicity from the introduction of PEG and the degradation of the copolymer into low molecular weight PEIs. Reaction conditions were carefully controlled to produce water soluble copolymers. Results from a gel retardation assay and zetapotentiometer indicated that complete neutralization of the complexes was achieved at the charge ratios of copolymer/pSV-β-gal plasmid from 0.8 to 1.0 with the mean particle size of the polyplexes ranging from 129.8±0.9 to 151.8±3.4 nm. In vitro transfection efficiency of the synthesized copolymer increased up to three times higher than that of starting low molecular weight PEI, while the cell viability was maintained over 80%.     

Synergistic effect of ultrasound and PEI on DNA transfection in vitro.

Ultrasound and poly(ethylenimine) (PEI) have each separately been shown to increase DNA transfection efficiency. This study tested the hypothesis that the combination of ultrasound and PEI can have a synergistic effect to increase DNA transfection. This in vitro study assessed transfection efficiency of two different DNA plasmids encoding green fluorescent protein and firefly luciferase in two different cell types, a primary culture of human aortic smooth muscle cells and an immortal line of human prostate cancer cells. We found that ultrasound sonication increased transfection up to 18-fold, DNA complexation with PEI increased transfection up to 90-fold, and the combination of ultrasound and PEI synergistically increased transfection up to 200-fold, which resulted in reporter gene expression by 34% of cells. Kinetic measurements found that the effects of ultrasound alone acted quickly, whereas increased transfection by PEI either alone or in combination with ultrasound strongly benefited from a 4-h incubation with the DNA plasmid after sonication. Although serum reduced absolute expression levels, it did not affect the relative increase in transfection when ultrasound was added to PEI enhancement. Flow cytometry measurements showed that sonication increased intracellular uptake of labeled DNA complexed to PEI by 55% relative to PEI complexation alone. Electrophoresis assay showed no damage to DNA or PEI-DNA complexes after sonication. Overall, these results suggest that the combination of ultrasound and PEI can have a synergistic effect to increase DNA transfection.     

New polyphosphoramidate with a spermidine side chain as a gene carrier.

A new cationic polymer (PPA-SP), polyphosphoramidate bearing spermidine side chain, was prepared as a non-viral vector for gene delivery. PPA-SP was synthesized from poly(1,2-propylene H-phosphonate) by the Atherton-Todd reaction. The weight average molecular weight of PPA-SP was 3.44x10(4) with a number average degree of polymerization of 90, as determined by GPC/LS/RI method. The average net positive charge per polymer chain was 102. PPA-SP was able to condense plasmid DNA efficiently and formed complexes at an N/P ratio (free amino groups in polymer to phosphate groups in DNA) of 2 and above, as determined by agarose gel electrophoresis. This new gene carrier offered significant protection to DNA against nuclease degradation at N/P ratios above 2, and showed lower cytotoxicity than PLL and PEI in cell culture. The LD(50) of PPA-SP was 85 microg/ml in COS-7 cells, in contrast to 20 and 42 microg/ml for PLL and PEI, respectively. The complexes prepared in saline at N/P ratios of 5 approximately 10 had an average size of 250 nm and zeta-potential of 26 mV. PPA-SP mediated efficient gene transfection in a number of cell lines, and the transfection protocol was optimized in HEK293 cells using a luciferase plasmid as a marker gene. Gene expression mediated by PPA-SP was greatly enhanced when chloroquine was used in conjunction at a concentration of 100 microM. Under the optimized condition, PPA-SP/DNA complexes yield a luciferase expression level closed to PEI/DNA complexes or Transfast mediated transfection. In a non-invasive CNS gene delivery model, PPA-SP/DNA complexes yielded comparable bcl-2 expression as PEI/DNA complexes in mouse brain stem following injection of the complexes in the tongue.     

A novel environment-sensitive biodegradable polydisulfide with protonatable pendants for nucleic acid delivery

Clinical application of nucleic acid-based therapies is limited by the lack of safe and efficient delivery systems. The purpose of this study is to design and evaluate novel biodegradable polymeric carriers sensitive to environmental changes for efficient delivery of nucleic acids, including plasmid DNA and siRNA. A novel polydisulfide with protonatable pendants was synthesized by the oxidative polymerization of a dithiol monomer, which was readily prepared by solid phase chemistry. The polydisulfide exhibited good buffering capacity and low cytotoxicity. It formed stable complexes with both plasmid DNA and siRNA. The particle sizes of the complexes decreased with the increase of the N/P ratios in the range of 100 to 750 nm. The complexes were stable in the presence of salt and heparin under normal physiological conditions, but dissociated to release nucleic acids in a reductive environment similar to cytoplasm. The polydisulfide demonstrated N/P ratio dependent transfection efficiency for plasmid DNA and gene silencing efficiency for siRNA. The presence of an endosomal disrupting agent, chloroquine, did not affect the DNA transfection efficiency of the polydisulfide. The transfection or gene silencing efficiency of the polydisulfide/DNA or siRNA complexes was comparable to or slightly lower than that of corresponding PEI complexes. Moreover, the polydisulfide showed better serum-friendly feature than PEI when delivering either DNA or siRNA in the presence of 10% FBS. This novel polydisulfide is a promising lead for further design and development of safe and efficient delivery systems for nucleic acids.     

DNA nano-carriers from biodegradable cationic branched polyesters are formed by a modified solvent displacement method.

DNA nano-carriers were formulated relying on biodegradable polyesters consisting of amine-modified poly(vinyl alcohol) (PVAL) backbones grafted with PLGA, based on the Marangoni effect thus avoiding detrimental shear or ultrasonic forces. These amine modified high molecular weight biodegradable polyesters combine specific characteristics, such as electrostatic interactions between DNA and cationic branched polyesters facilitating loading of NP with DNA. The resulting DNA containing NP showed hydrodynamic diameters in the range of 175-285 nm and highly positive xi-potentials, depending on the nitrogen to phosphate (N/P) ratio used for the particle formation. Atomic force microscopy (AFM) demonstrated well-defined spherical particle morphologies. DNA was released from NP upon incubation in PBS buffer in its intact supercoiled form. Agarose gel electrophoresis demonstrated that DNA within the NP was protected from enzyme degradation. The biological efficiency of the DNA delivery by this nano-carrier was demonstrated by an in vitro transfection assay using four cell lines. Reporter gene delivery of the amine-modified polymers was higher than naked DNA (Control) and raised with increasing degree of amine substitution. Also type of amine and distance of cationic charge from the backbone play an important role. Further, this feature was shown by Luciferase expression of the pCMV-Luc plasmid with PEI 25 kDa/DNA polyplexes and NP prepared with amine modified polyesters with a grafted PLGA chain length of 10 monomers compared at equal N/P ratios. DNA loaded NP from P(68)-10 showed 8x higher transfection efficiencies than the PEI 25 kDa at an N/P ratio of 9 for both preparations. These novel DNA nano-carriers merit further investigations in particular for DNA vaccination under in vivo conditions.     

Polylysine-modified polyethylenimine inducing tumor apoptosis as an efficient gene carrier

Polyethylenimine (PEI) is receiving increasing attention as a gene carrier with high transfection efficiency. However, its high charge density and cytotoxic effects limit its application. Polylysine (PLL) is another polymeric gene carrier with good biodegradability and biocompatibility, although its lack of endosomal escape ability strongly impairs its transfection efficiency. In this study, PLL was introduced to PEI by ring-opening polymerization of ε-benzyloxycarbonyl-l-lysine N-carboxyanhydride, followed by deprotection of carbobenzyloxy groups. As-prepared PEI-PLL multiarm hyperbranched copolymers were characterized as gene carriers in vitro by measuring their particle size, zeta potential, cytotoxicity, transfection efficiency, and cell internalization. The optimum transfected efficiency of PEI-PLL was nearly seven times higher than that of PEI with a molecular weight of 25 kDa. Furthermore, pKH3-rev-casp-3 plasmid DNA was used as a gene for anti-tumor treatment in a xenograft model using nude mice. Compared with 25 kDa PEI, PEI-PLL exhibited better tumor inhibition effects in 23 days. In addition, terminal deoxynucleotidyl transferase dUTP nick end labeling, immunohistochemistry, and western blot analysis were used to determine the anti-tumor mechanism of PEI-PLL. The results showed that tumor cell apoptosis led to tumor inhibition, which could be attributed to pKH3-rev-casp-3 inducing poly(ADP-ribose) polymerase-1 cleavage. PEI-PLL is a promising gene carrier candidate for further application in vivo.     

Synergistic effect of poly(ethylenimine) on the transfection efficiency of galactosylated chitosan/DNA complexes.

The use of chitosan for gene delivery is limited due to the low transfection efficiency and difficulty in transfecting into a variety of cell types, especially the hepatoma cells. In order to solve this problem, lactobionic acid (LA) bearing galactose group was coupled with water-soluble chitosan (WSC) for liver specificity and poly(ethylenimine) (PEI) was combined to galactosylated chitosan (GC)/DNA complexes to enhance the transfection efficiency. For initial study, the effect of PEI on the transfection efficiency of WSC/DNA complex was studied in HeLa, A549 and 293 T cells, and bafilomycin A1 was used to ascertain the mechanism of synergistic effect. Transfection efficiency, cytotoxicity, and physicochemical properties of GC/DNA complex combined with PEI were investigated to determine the potential for the hepatocyte-targeting. The combination of PEI with WSC/DNA and GC/DNA complex dramatically increased the luciferase expression 10- to 1000-fold in various cell lines, and the synergistic effect was proved to be induced by proton sponge effect of PEI. The transfection of GC/DNA complex in HepG2 was much higher than that of WSC/DNA even after combination with PEI, and was highly inhibited in the presence of galactose. Cytotoxicity of PEI was much decreased by combination with GC/DNA complex. And PEI was proved to be coated on the surface of GC/DNA complex through the ionic interaction.     

Transfer of YACs up to 2.3 Mb intact into human cells with polyethylenimine.

The transfer of large YAC DNA into human cells is a laborious procedure. High quality pulsed field gel purified DNA is required, which is easily sheared during manipulation before transfection or degraded in the endosome of the cell following transfection. NaCl and polyamines compact and prevent DNA from shearing, but may not consistently protect DNA after transfection. We investigated if other polycations such as poly-L-lysine (PLL) and polyethylenimine (PEI) could condense and protect large YAC DNA (up to 2.3 Mb) from being degraded after lipofection. DNA condensation was monitored by a gel retardation assay, and atomic force microscopy (AFM). DNA was retarded in the gel when complexed with high concentrations of PLL and PEI, indicating that DNA had condensed. However, AFM images of PLL-DNA complexes showed aggregates of DNA molecules resulting from incomplete condensation, whereas PEI-DNA complexes produced condensed particles approximately 30-60 nm. Exogenous PLL-DNA remained intact in 36% of positive clones after lipofection, whereas PEI-DNA was intact in 100% of positive clones. PEI is a better condensing reagent than PLL, protecting DNA from shearing and endosomal degradation, and assists in delivering YACs up to 2.3 Mb intact into human cells.