PEG grafting of polyethylenimine (PEI) exerts different effects on DNA transfection and siRNA-induced gene targeting efficacy

BACKGROUND: Gene targeting by RNA interference (RNAi) is mediated through small interfering RNA (siRNA), which, as plasmid DNA molecules, can be delivered into cells by polyethylenimines (PEI). Grafting with poly(ethylene glycol) has been introduced previously to improve PEI biocompatibility; however, data on the effects of PEGylation have been somewhat contradictory and various PEI(-PEG) need to be evaluated independently for DNA transfection and siRNA gene targeting efficacies. AIM: We directly compare plasmid DNA transfection and siRNA-mediated gene targeting efficacies, employing a larger set of polyethylenimine-graft-poly(ethylene glycol) (PEI-g-PEG; PEI(-PEG)) with different molecular weights and degrees of PEG substitution. METHOD: We performed tissue culture-based bioassays on DNA transfection and siRNA-mediated targeting efficacies as well as on toxicity and cellular nucleic acid uptake, and, using sensitive assays based on radioactive labelling, physicochemically characterize the complexes regarding the degree of nucleic acid complexation and complex stabilities under various conditions. RESULTS: In contrast to the DNA transfection efficacy, siRNA-mediated gene targeting is much less dependent on the PEGylation of PEI or on the N/P ( = PEI nitrogen/nucleic acid phosphate) ratio. A more detailed analysis reveals that, in order to define optimal N/P ratios for DNA transfection, complex toxicities and nucleic acid uptake are the most critical parameters. In contrast, at optimal N/P ratios, complex stabilities and complexation efficacies determine PEI(-PEG)/DNA transfection efficacies and the major differences between various PEI(-PEG) are observed. All these parameters are less critical for PEI(-PEG)/siRNA gene targeting efficacy. Thus, our data lead to the distinction between three PEI(-PEG) groups, which relies on the differences in transfection rather than gene targeting efficacies, and which is correlated with the molecular weights and degrees of PEG substitution. CONCLUSION: In contrast to PEI(-PEG)/DNA complexes, a broader panel of PEI-PEG are capable of siRNA-mediated gene targeting. Thus, PEG grafting of PEI requires a separate evaluation of siRNA and DNA complexes, which expands the portfolio of available PEI(-PEG) for the preparation of non-toxic, biocompatible siRNA delivery reagents for the induction of RNAi.     

PEG grafting of polyethylenimine (PEI) exerts different effects on DNA transfection and siRNA-induced gene targeting efficacy

Background: Gene targeting by RNA interference (RNAi) is mediated through small interfering RNA (siRNA), which, as plasmid DNA molecules, can be delivered into cells by polyethylenimines (PEI). Grafting with poly(ethylene glycol) has been introduced previously to improve PEI biocompatibility; however, data on the effects of PEGylation have been somewhat contradictory and various PEI(-PEG) need to be evaluated independently for DNA transfection and siRNA gene targeting efficacies.

Aim: We directly compare plasmid DNA transfection and siRNA-mediated gene targeting efficacies, employing a larger set of polyethylenimine-graft-poly(ethylene glycol) (PEI-g-PEG; PEI(-PEG)) with different molecular weights and degrees of PEG substitution.

Method: We performed tissue culture-based bioassays on DNA transfection and siRNA-mediated targeting efficacies as well as on toxicity and cellular nucleic acid uptake, and, using sensitive assays based on radioactive labelling, physicochemically characterize the complexes regarding the degree of nucleic acid complexation and complex stabilities under various conditions.

Results: In contrast to the DNA transfection efficacy, siRNA-mediated gene targeting is much less dependent on the PEGylation of PEI or on the N/P (= PEI nitrogen/nucleic acid phosphate) ratio. A more detailed analysis reveals that, in order to define optimal N/P ratios for DNA transfection, complex toxicities and nucleic acid uptake are the most critical parameters. In contrast, at optimal N/P ratios, complex stabilities and complexation efficacies determine PEI(-PEG)/DNA transfection efficacies and the major differences between various PEI(-PEG) are observed. All these parameters are less critical for PEI(-PEG)/siRNA gene targeting efficacy. Thus, our data lead to the distinction between three PEI(-PEG) groups, which relies on the differences in transfection rather than gene targeting efficacies, and which is correlated with the molecular weights and degrees of PEG substitution.

Conclusion: In contrast to PEI(-PEG)/DNA complexes, a broader panel of PEI-PEG are capable of siRNA-mediated gene targeting. Thus, PEG grafting of PEI requires a separate evaluation of siRNA and DNA complexes, which expands the portfolio of available PEI(-PEG) for the preparation of non-toxic, biocompatible siRNA delivery reagents for the induction of RNAi.     

Evaluation of the transfection property of a peptide ligand for the fibroblast growth factor receptor as part of PEGylated polyethylenimine polyplex

PURPOSE: Experiments were conducted to evaluate the utility of a peptide receptor ligand to improve transfection efficiency as part of a polyethylenimine-polyethylene glycol (PEI-PEG) polyplex. The 7-mer peptide (MQLPLAT), targeted toward the fibroblast growth factor 2 (FGF2) receptor, was recently identified using a phage-display library method as possessing a high degree of specificity for the FGF2 receptor without the mutagenicity associated with FGF itself. Two approaches (pre-modification or post-modification) to incorporate the peptide into the PEGylated polyplex were compared in terms of their effect on particle size, surface charge, DNA condensation ability, toxicity, cellular uptake and transfection efficiency. METHODS: The peptide was conjugated to branched PEI (25 kDa) via a PEG spacer either before (pre-modified) or after (post-modified) complexation of PEI with DNA. Polyethyleneimine was conjugated to the PEG spacer (N-hydroxy succinimide (NHS) -PEG-maleimide (Mal)) through the NHS group. The FGF2 peptide was synthesized to contain a cysteine at the carboxyl end (MQLPLATC) and conjugated to the PEG spacer via the Maleimide group. Conjugates were evaluated using (1)H NMR, amino acid analysis, and picrylsulfonic acid assay. DNA condensation was evaluated using agarose gel electrophoresis and cellular toxicity was determined using the 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide (MTT) assay. Cellular uptake was measured using flow cytometry and transfection efficiency was determined using a luciferase reporter gene assay. RESULTS: Both pre- and post-modification approaches led to a decrease in the zeta potential of the resulting polyplexes but did not alter their size. The pre-modification of PEI did not affect its ability to condense DNA. However, polyplexes formed with the pre-conjugated PEI did not improve cell uptake or transfection efficiency. In contrast, polyplexes that were post-modified with the FGF2 peptide resulted in a 3-fold increase in cell uptake and a 6-fold increase in transfection efficiency. Both pre- and post-modified polyplexes resulted in lower toxicity compared with unmodified PEI. CONCLUSIONS: The results indicate that the FGF2 peptide improves transfection efficiency when used as part of post-modified PEI/PEG polyplex. When used with pre-modified PEI/PEG, the beneficial effect of the peptide on transfection is not evident, probably because, in this case, the peptide ligand is not readily accessible to the FGF receptor.     

Secure and effective gene delivery system of plasmid DNA coated by polynucleotide

Polynucleotides are anionic macromolecules which are expected to transfer into the targeted cells through specific uptake mechanisms. So, we developed polynucleotides coating complexes of plasmid DNA (pDNA) and polyethylenimine (PEI) for a secure and efficient gene delivery system and evaluated their usefulness. Polyadenylic acid (polyA), polyuridylic acid (polyU), polycytidylic acid (polyC), and polyguanylic acid (polyG) were examined as the coating materials. pDNA/PEI/polyA, pDNA/PEI/polyU, and pDNA/PEI/polyC complexes formed nanoparticles with a negative surface charge although pDNA/PEI/polyG was aggregated. The pDNA/PEI/polyC complex showed high transgene efficiency in B16-F10 cells although there was little efficiency in pDNA/PEI/polyA and pDNA/PEI/polyU complexes. An inhibition study strongly indicated the specific uptake mechanism of pDNA/PEI/polyC complex. Polynucleotide coating complexes had lower cytotoxicity than pDNA/PEI complex. The pDNA/PEI/polyC complex showed high gene expression selectively in the spleen after intravenous injection into mice. The pDNA/PEI/polyC complex showed no agglutination with erythrocytes and no acute toxicity although these were observed in pDNA/PEI complex. Thus, we developed polynucleotide coating complexes as novel vectors for clinical gene therapy, and the pDNA/PEI/polyC complex as a useful candidate for a gene delivery system.     

Targeted drug delivery via the transferrin receptor-mediated endocytosis pathway

The membrane transferrin receptor-mediated endocytosis or internalization of the complex of transferrin bound iron and the transferrin receptor is the major route of cellular iron uptake. This efficient cellular uptake pathway has been exploited for the site-specific delivery not only of anticancer drugs and proteins, but also of therapeutic genes into proliferating malignant cells that overexpress the transferrin receptors. This is achieved either chemically by conjugation of transferrin with therapeutic drugs, proteins, or genetically by infusion of therapeutic peptides or proteins into the structure of transferrin. The resulting conjugates significantly improve the cytotoxicity and selectivity of the drugs. The coupling of DNA to transferrin via a polycation or liposome serves as a potential alternative to viral vector for gene therapy. Moreover, the OX26 monoclonal antibody against the rat transferrin receptor offers great promise in the delivery of therapeutic agents across the blood-brain barrier to the brain.     

PEG修饰对PEI聚电解质复合物的药学特性及人乳腺癌细胞的摄取效率影响的研究

荧光素阴离子葡聚糖（DFA）和寡核苷酸（ODN）可以和带正电的聚乙亚胺（PEI）通过自组装的方式形成聚电解质复合物。为了调查PEG修饰对PEI聚电解质复合物的药学特性及细胞摄取效率的影响，我们进行了此项研究。DFA和ODN与PEI及PEI—PEG通过吹吸混匀形成聚电解质复合物。我们分别采用动态光散射法及琼脂糖凝胶电泳法对聚电解质复合物的表面性质（粒径，ξ电位），PEI及PEI—PEG延滞ODN的能力等进行了评价。MCF-7对DFA／PEI及DFA／PEI-PEG的摄取效率通过流式细胞术进行测量，并通过激光扫描聚焦显微镜（CLSM）法来观察DFA／PEI及DFA／PEI—PEG聚电解质复合物的细胞内摄作用。N／P比对ODN／PEI聚电解质复合物的粒径和ξ电位影响很大，而ODN／PEI—PEG复合物的粒径受N／P比的影响要小一些，在N／P=2～16范围内，ODN／PEI—PEG复合物的粒径在30～100nm左右。PEI和PEI—PEG在N／P比等于4时就开始出现延滞ODN的现象，彻底延滞在N／P比等于8时出现。MCF-7的细胞摄取效率与DFA浓度及转染时间呈正相关，在适宜条件下，细胞摄取率可超过99％。本实验结果显示通过隐形修饰的PEI自组装形成的聚电解质复合物可以提高其作为基因载体递送基因进入细胞的能力。     

Evaluation of transferrin-polyethylenimine conjugate for targeted gene delivery

With the aim to improve the specificity and to reduce the cytotoxicity of polyethylenimine (PEI), we have synthesized the conjugates of the branched PEI (25 kDa) with transferrin. The transferrin-PEI (TP) conjugates with five compositions were synthesized using periodate oxidation method and confirmed by FT-IR spectroscopy and gel permeation chromatography. The free amine contents of TP conjugates, which were able to condense and deliver DNA, increased as the amount of PEI increased. TP/DNA polyplexes were characterized by measuring gel electrophoresis, ethidium bromide fluorescence quenching, particle size and zeta potential of complexes. Complete complexation of the polyplexes was observed above the N/P ratio of 5 in TP/ DNA, and above 3 in PEI/DNA, respectively. The zeta potential of the complexes decreased as the amount of transferrin in TP conjugates increased. Transfection efficiency of TP conjugates was evaluated in HeLa cell and Jurkat cell systems. Among the five compositions of TP conjugates, TP-2 system mediated a higher beta-galactosidase gene expression than PEI system in Jurkat cell which was known to express elevated numbers of transferrin receptors. From the results of the cell viability based on MTT assay, TP conjugates showed lower cytotoxicity compared with the PEI system. We expect that the TP conjugate can be used efficiently as a nonviral gene delivery vector.     

Enhanced Gene Transfection in Macrophages Using Mannosylated Cationic Liposome-Polyethylenimine-Plasmid DNA Complexes

We have previously reported that plasmid DNA and cholesten-5-yloxy-N-{4-[(1-imino-2-β-D-tWomannosylethyl)amino]butyl}forrnarnide(Man-C4-Chol)/dioleoylphosphatidylethanolamine(DOPE)(6:4) liposome complexes (DNA/Man-complexes) exhibit efficient gene transfection in macrophages via mannose receptor-mediated endocytosis. To further enhance gene transfetion, polyethylenimine (PEI) was incorporated into this liposome complex (DNA/Man-PEI-complexes), noticing a pH-buffering capacity in endosomes and DNA-condensing activity of PEI. In mouse peritoneal macrophages, the uptake and transfection activity of DNA/Man-PEI-complexes were 2-times and 6-times higher than those of DNA/Man-complexes, respectively. Furthermore, the presence of 1 mg/ml mannan significantly inhibited both the uptake and transfection efficiency of DNA/Man-PEI-complexes. These results suggested that the newly developed multifunctional DNA/Man-PEI-complexes exhibit highly improved gene transfection in macrophages via mannose receptor-mediated endocytosis.     

Evaluation of the transfection property of a peptide ligand for the fibroblast growth factor receptor as part of PEGylated polyethylenimine polyplex

Purpose: Experiments were conducted to evaluate the utility of a peptide receptor ligand to improve transfection efficiency as part of a polyethylenimine-polyethylene glycol (PEI-PEG) polyplex. The 7-mer peptide (MQLPLAT), targeted toward the fibroblast growth factor 2 (FGF2) receptor, was recently identified using a phage-display library method as possessing a high degree of specificity for the FGF2 receptor without the mutagenicity associated with FGF itself. Two approaches (pre-modification or post-modification) to incorporate the peptide into the PEGylated polyplex were compared in terms of their effect on particle size, surface charge, DNA condensation ability, toxicity, cellular uptake and transfection efficiency.

Methods: The peptide was conjugated to branched PEI (25 kDa) via a PEG spacer either before (pre-modified) or after (post-modified) complexation of PEI with DNA. Polyethyleneimine was conjugated to the PEG spacer (N-hydroxy succinimide (NHS) -PEG-maleimide (Mal)) through the NHS group. The FGF2 peptide was synthesized to contain a cysteine at the carboxyl end (MQLPLATC) and conjugated to the PEG spacer via the Maleimide group. Conjugates were evaluated using ¹H NMR, amino acid analysis, and picrylsulfonic acid assay. DNA condensation was evaluated using agarose gel electrophoresis and cellular toxicity was determined using the 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide (MTT) assay. Cellular uptake was measured using flow cytometry and transfection efficiency was determined using a luciferase reporter gene assay.

Results: Both pre- and post-modification approaches led to a decrease in the zeta potential of the resulting polyplexes but did not alter their size. The pre-modification of PEI did not affect its ability to condense DNA. However, polyplexes formed with the pre-conjugated PEI did not improve cell uptake or transfection efficiency. In contrast, polyplexes that were post-modified with the FGF2 peptide resulted in a 3-fold increase in cell uptake and a 6-fold increase in transfection efficiency. Both pre- and post-modified polyplexes resulted in lower toxicity compared with unmodified PEI.

Conclusions: The results indicate that the FGF2 peptide improves transfection efficiency when used as part of post-modified PEI/PEG polyplex. When used with pre-modified PEI/PEG, the beneficial effect of the peptide on transfection is not evident, probably because, in this case, the peptide ligand is not readily accessible to the FGF receptor.     

Cellular Uptake of Cationic Polymer-DNA Complexes Via Caveolae Plays a Pivotal Role in Gene Transfection in COS-7 Cells

Purpose Knowledge about the uptake mechanism and subsequent intracellular routing of non-viral gene delivery systems is important for the development of more efficient carriers. In this study we compared two established cationic polymers pDMAEMA and PEI with regard to their transfection efficiency and mechanism of cellular uptake. Materials and Methods The effects of several inhibitors of particular cellular uptake routes on the uptake of polyplexes and subsequent gene expression in COS-7 cells were investigated using FACS and transfection. Moreover, cellular localization of fluorescently labeled polyplexes was assessed by spectral fluorescence microscopy. Results Both pDMAEMA- and PEI-complexed DNA showed colocalization with fluorescently-labeled transferrin and cholera toxin after internalization by COS-7 cells, which indicates uptake via the clathrin- and caveolae-dependent pathways. Blocking either routes of uptake with specific inhibitors only resulted in a marginal decrease in polyplex uptake, which may suggest that uptake routes of polyplexes are interchangeable. Despite the marginal effect of inhibitors on polyplex internalization, blocking the caveolae-mediated uptake route resulted in an almost complete loss of polyplex-mediated gene expression, whereas gene expression was not negatively affected by blocking the clathrin-dependent route of uptake. Conclusions These results show the importance of caveolae-mediated uptake for successful gene expression and have implications for the rational design of non-viral gene delivery systems.     

Analysis of hepatic disposition of native and galactosylated polyethylenimine complexed with plasmid DNA in perfused rat liver

We studied the intrahepatic disposition characteristics of galactosylated polyethylenimine (Gal-PEI)/plasmid DNA (pDNA) complexes using rat liver perfusion experiment. After intraportal administration, transfection activity in liver of Gal-PEI complexes was approximately 26-fold higher than that of native PEI complexes. To evaluate the relationship between hepatic gene expression and disposition profiles, hepatic disposition of Gal-PEI complexes were pharmacokinetically analyzed by use of perfused rat liver, which enables uptake characteristics intrinsic to the liver to be elucidated. Moment analysis revealed that both complexes exhibited very high single-pass extraction. To characterize each kinetic process in hepatic uptake of Gal-PEI complexes, their outflow profiles were analyzed based on a two-compartment dispersion model. Consequently, the tissue binding affinity of Gal-PEI complexes was 3.0-fold larger than that of native PEI complexes, suggesting the increasing of hepatic binding affinity much enhanced the hepatic gene transfection efficiency. In contrast, galactosylation of PEI did not affected internalization (and/or sequestration) rate.     

In vivo pharmacokinetics, tissue distribution and underlying mechanisms of various PEI(-PEG)/siRNA complexes

Background

RNA interference (RNAi) represents a novel therapeutic strategy allowing the knockdown of any pathologically relevant target gene. Since it relies on the action of small interfering RNAs (siRNAs), the in vivo delivery of siRNAs is instrumental. Polyethylenimines (PEIs) and PEGylated PEIs have been shown previously to complex siRNAs, thus mediating siRNA protection against nucleolytic degradation, cellular uptake and intracellular release.

Purpose

The present study determines in vivo pharmacokinetics, tissue distribution/efficacy of siRNA delivery and adverse effects of a broad panel of PEI(-PEG)-based siRNA complexes. The aim is to systematically evaluate the effects of different degrees and patterns of PEGylation in PEI-PEG copolymers on the in vivo behavior of PEI(-PEG)/siRNA complexes in mice.

Results

Upon i.v. injection of radioactively labeled, PEI(-PEG) complexed siRNAs, marked differences in the pharmacokinetics and biodistribution of the complexes are observed, with the fate of the PEI(-PEG)/siRNA complexes being mainly dependent on the degree of uptake in liver, spleen, lung and kidney. Thus, the role of these tissues is investigated in greater detail using representative PEI(-PEG)/siRNA complexes. The induction of erythrocyte aggregation and hemorrhage is dependent on the degree and pattern of PEGylation as well as on the PEI/siRNA (N/P) ratio, and represents one important effect in the lung. Furthermore, siRNA uptake in liver and spleen, but not in lung or kidney, is mediated by macrophage and is dependent on macrophage activity. In the kidney PEI(-PEG)/siRNA uptake is mostly passive and reflects the total stability of the complexes.

Conclusion

Liver, lung, spleen and kidney are the major players determining the in vivo biodistribution of PEI(-PEG)/siRNA complexes. Beyond their physicochemical and in vitro bioactivity characteristics, PEI(-PEG)/siRNA complexes show marked differences in vivo which can be explained by distinct effects in different tissues. Based on these data, our study also identifies which PEGylated PEIs are promising tools for in vivo siRNA delivery in future therapeutic studies and which major determinants require further investigation.     

PEGylation affects cytotoxicity and cell-compatibility of poly(ethylene imine) for lung application: Structure-function relationships

Poly(ethylene imine) (PEI) has widely been used as non-viral gene carrier due to its capability to form stable complexes by electrostatic interactions with nucleic acids. To reduce cytotoxicity of PEI, several studies have addressed modified PEIs such as block or graft copolymers containing cationic and hydrophilic non-ionic components. Copolymers of PEI and hydrophilic poly(ethylene glycol) (PEG) with various molecular weights and graft densities were shown to exhibit decreased cytotoxicity and potential for DNA and siRNA delivery.In this study, we evaluated the cytotoxicity and cell-compatibility of different PEGylated PEI polymers in two murine lung cell lines. We found that the degree of PEGylation correlated with both cytotoxicity and oxidative stress, but not with proinflammatory effects. AB type copolymers with long PEG blocks caused high membrane damage and significantly decreased the metabolic activity of lung cells. In addition, they significantly increased the release of two lipid mediators such as 8-isoprostanes (8-IP) and prostaglandin E₂ (PGE₂) in a dose-dependent manner. In contrast, the cytokine profiles which indicated high levels of acute-phase cytokines such as TNF-α, IL-6, and G-CSF did not follow any clear structure-function relationship.In conclusion, we found that modification of PEI 25kDa with high degree of PEGylation and low PEG chain length reduced cytotoxic and oxidative stress response in lung cells, while the proinflammatory potential remained unaffected. A degree of substitution in the range of 10 to 30 and PEG-chain lengths up to 2000 Da seem to be beneficial and merit further investigations.     

Novel biotinylated chitosan-graft-polyethyleneimine copolymer as a targeted non-viral vector for anti-EGF receptor siRNA delivery in cancer cells

The major impediments to develop an efficient non-viral siRNA-mediated gene silencing method, as a therapeutic approach, are the low cellular uptake and intracellular delivery and release of non-viral vectors. To overcome these problems, designing a proper vector with high transfection efficiency is obviously under scrutiny of various studies. The present study, evaluate a novel biotinylated chitosan-graft-polyethyleneimine (Bio-Chi-g-PEI) copolymer as an appropriate non-viral vector for targeted delivery of siRNA to cancer cells. The composition of the synthesized Bio-Chi-g-PEI copolymer was thoroughly characterized using ¹H NMR and FTIR spectroscopy, besides the hydroxyazobenzene-2-carboxylic acid (HABA) assay. In vitro cytotoxicity assay of the Bio-Chi-g-PEI copolymers was performed by MTT assay. Cytotoxicity evaluations indicated that the new copolymer was markedly less toxic than PEI 25KD. Physicochemical properties of the Bio-Chi-g-PEI/siRNA complexes such as complex stability, size, zeta potential, and their morphology at various weight ratios, investigated by appropriate methods, revealed the suitability of the complexes for the transfection. The efficient cellular internalization of the complexes for HeLa and OVCAR-3 cells in culture media was confirmed by intracellular tracking of the prepared complexes using confocal laser scanning microscopy and Cy3-labeled anti-epidermal growth factor receptor siRNA. Finally, evaluation of the transfection efficiency and gene silencing by flow cytometry and real-time polymerase chain reaction highlighted the significantly higher efficiency of transfection and silencing for biotinylated copolymer compared with the PEI 25KD and non-biotinylated copolymer.     

Polyethylenimine PEI F25-LMW allows the long-term storage of frozen complexes as fully active reagents in siRNA-mediated gene targeting and DNA delivery.

Background: Polyethylenimines (PEIs) are synthetic, charged polymers which function as transfection reagents based on their ability to compact DNA into complexes. Recently, PEI-mediated delivery of nucleic acids has been extended towards small interfering RNAs (siRNAs) which are instrumental in the induction of RNA interference (RNAi). Since RNAi represents a powerful method for specific gene silencing, the PEI-based delivery of siRNAs is a promising tool for novel putative therapeutic strategies. Aim: For therapeutic use, major requirements are the development of formulations which (i) are sufficiently stable in the presence of serum, and which can be (ii) easily and reproducibly manufactured and (iii) stored for a prolonged time with full retention of their integrity and bioactivity. In this paper, we explore the potential of PEI F25-LMW, a low-molecular weight PEI with superior transfection efficacy and low toxicity, towards these goals. Results: We have systematically analyzed and determined optimal DNA and siRNA complexation conditions with regard to various parameters including buffer concentration, ionic strength, pH and incubation time. As opposed to 22kDa linear PEI (L-PEI), the low-molecular weight (4-10kDa) PEI F25-LMW performs DNA transfection and siRNA gene targeting with identical efficacies in the presence of serum, thus emphasizing its usefulness in vivo. Furthermore, in contrast to other polyethylenimines, PEI F25-LMW-based DNA or siRNA complexes allow freeze/thawing and frozen storage for several months. Their activity is fully retained without requiring specific buffer conditions or the addition of any lyoprotectant. Physicochemical analysis and atomic force microscopy reveal a distinct size pattern with the presence of two complex subgroups and show that frozen PEI F25-LMW complexes remain stable with little increase in complex size, no changes regarding their zeta potential and cytotoxicity, and full retention of nucleic acid protection. Conclusions: Frozen PEI F25-LMW-based complexes represent efficient and stable ready-to-use formulations of DNA- or siRNA-based gene therapy products.     

Inhibitory effect of a toxic peptide isolated from a waterbloom of Microcystis sp. (Cyanobacteria) on iron uptake by rabbit reticulocytes

The effect of a soluble toxin purified from the algae bloom of a eutrophic lake dominated by Microcystis on the receptor-mediated endocytosis of ferro-transferrin in rabbit reticulocytes was studied. The toxin was a very effective inhibitor of cell iron uptake. Kinetic studies using 125I, 59Fe-labeled transferrin indicated that the step of ferrotransferrin internalization was selectively inhibited by the toxin while the surface receptor-binding capacity, the externalization of previously internalized transferrin, and the cellular ATP levels were not affected. These findings indicate that the reduction of iron uptake caused by the toxin is due to inhibition of the internalization of surface-located transferrin-transferrin receptor complexes, perhaps due to a disruption of cytoskeleton integrity.     

Effect of Polyethylene Glycol Conjugated to DNA-Transfecting Complexes Targeted at the Transferrin Receptor of HeLa Cells

Modification of streptavidin (biotinylated transferrin)-biotinylated polylysine conjugates for DNA delivery by covalent addition of polyethylene glycol chains was investigated. It was found that addition of two to four monomethoxy-polyethylene glycol chains to bio²⁰-polylysine₁₀₀, a component of the transfecting conjugate, increased luciferase activity approximately four- to five-fold in a HeLa cell system. The increase occurred only in the presence of the lysosomotropic agent chloroquine and was inhibited by free transferrin. The latter result indicating that DNA uptake was via transferrin receptor-mediated endocytosis. Titration of cell cultures with transfecting complexes, with and without attached polyethylene glycol, showed luciferase activity to decrease at higher concentrations of the complexes. This was more marked with complexes containing polyethylene glycol. Complexes containing higher concentrations of attached polyethylene glycol inhibited luciferase expression strongly. Free polyethylene glycol at equivalent concentrations was without effect. It is suggested that at higher complex concentrations, the larger amounts of polyethylene glycol present occlude transferrin receptors, thus preventing uptake of DNA-containing complexes. The results indicate that transfecting complexes containing small amounts of polyethylene glycol function more efficiently than those without.     

Serum-resistant lipopolyplexes for gene delivery to liver tumour cells.

In this study, an efficient non-viral gene transfer system has been developed by employing polyethylenimine (PEI 800, 25 and 22kDa) and DOTAP and cholesterol (Chol) as lipids (lipopolyplex), at three different lipid/DNA molar ratios (2/1, 5/1 and 17/1) by using five different protocols of formulation. Condensation assays revealed that PEI of 800, 25 and 22kDa were very effective in condensing plasmid DNA, leading to a complete condensation at N/P ratios above 4. Addition of DOTAP/Chol liposomes did not further condense DNA. Increasing the molar ratio lipid/DNA in the complex resulted in higher positive values of the zeta-potential, while the particle size increased in some protocols, but not in others. High molecular weight PEI (800kDa) used in the formulation of lipopolyplexes lead to a bigger particle size, compared to that obtained with smaller PEI species, whether branched (25kDa) or linear (22kDa). These vectors were also highly effective in protecting DNA from attack by DNAse I. Transfection activity was maximal by using protocols 3 and 4 and a lipid/DNA molar ratio of 17/1. These complexes showed high efficiency in gene delivery of DNA to liver cancer cells, even in the presence of high concentration of serum (60% FBS). On the other hand, complexes formed with linear PEI (22kDa) were more effective than lipopolyplexes containing branched PEI (800 or 25kDa). The complexes resulted to be much more efficient than conventional lipoplexes (cationic lipid and DNA) and polyplexes (cationic polymer and DNA). The same behaviour was observed for complexes prepared in the presence of the therapeutic gene pCMVIL-12. Toxicity assays revealed a viability higher than 80% in all cases, independently of the protocol, molar ratio (lipid/DNA), molecular weight and type of PEI.     

Skin photoprotection improvement: synergistic interaction between lipid nanoparticles and organic UV filters

The main objective of this study was to prepare two types of nanoparticles with poly(d,l-lactide-co-glycolide) (PLGA) and polyethylenimine (PEI) polymers. Plasmid DNA (pDNA) was adsorbed either on PLGA/PEI nanoparticles, or as PEI/DNA complex onto the surface of PLGA nanoparticles. Both types of nanoparticles were prepared by the double emulsion method. The nanoparticles were characterized by their size, zeta potential and pDNA or PEI/DNA complex adsorption. The PEI/DNA complex adsorption was confirmed with ethidium bromide assay. pDNA adsorption onto PLGA/PEI nanoparticles (PLGA/PEI-DNA) was studied by electrophoresis on agarose gel. Cytotoxicity and transfection efficiency of both types of nanoparticle and PEI/DNA complexes formulations were studied in head and neck squamous carcinoma cell line (FaDu). To improve endosomal release, photochemical internalization (PCI) was used. The zeta potential increased when the PEI/DNA complex adsorbed onto PLGA nanoparticles (PLGA-PEI/DNA). Optimal pDNA adsorption efficiency was achieved for nitrogen/phosphorous ratio≥20/1. In vitro transfection and cells viability on FaDu cells with or without PCI were found to be variable depending on the type and concentration of nanoparticles. The results showed that transfection efficiency for PLGA/PEI-DNA or PLGA-PEI/DNA nanoparticles ranged between 2 and 80%, respectively. PCI was found to slightly improve the transfection efficiency for all formulations.     

Biophysical and biological investigation of DNA nano-complexes with a non-toxic, biodegradable amine-modified hyperbranched polyester

Designed for gene therapy of chronic diseases, HBP-DEAPA 60 is a non-toxic biodegradable amine modified hyperbranched polyester. This candidate was chosen from a series of hyperbranched polymers for further characterization as it showed the best transfection efficiency and fastest degradation rate. HBP-DEAPA 60/DNA complexes were investigated with regard to stability, uptake and formation to gain a better insight into HBP-DEAPA 60/DNA complex properties. We investigated HBP-DEAPA 60/DNA complex uptake into A 549 cells by FACS and CLSM. Their stability was investigated by a heparin displacement assay as well as by DNAse I assay. Morphology was shown by AFM. HBP-DEAPA 60/DNA complex formation was further characterized in terms of thermodynamic parameters. We studied the conformation of DNA in nano-complexes via circular dichroism (CD) spectroscopy for different NP ratios. Thermodynamic studies showed that binding enthalpies were endothermic; the nano-complex formation was entropically driven. Although PEI/DNA and HBP-DEAPA 60/DNA complexes showed similar behavior with regard to uptake, heparin stability, DNA helicality and their entropically driven complex formation they differ in their binding constant K(a) and in their ability to protect the DNA from DNAse. Concerning K(a) and DNAse stability, HBP-DEAPA/DNA complexes should be further optimized. This shows that different characterization studies are necessary to fully characterize polyplex stability and properties.