Genuine DNA/polyethylenimine (PEI) Complexes Improve Transfection Properties and Cell Survival

Polyethylenimine (PEI) has been described as one of the most efficient cationic polymers for in vitro gene delivery. Systemic delivery of PEI/DNA polyplexes leads to a lung-expression tropism. Selective in vivo gene transfer would require targeting and stealth particles. Here, we describe two strategies for chemically coupling polyethylene glycol (PEG) to PEI, to form protected ligand-bearing particles. Pre-grafted PEG–PEI polymers lost their DNA condensing property, hence their poor performances. Coupling PEG to pre-formed PEI/DNA particles led to the expected physical properties. However, low transfection efficacies raised the question of the fate of excess free polymer in solution. We have developed a straightforward a purification assay, which uses centrifugation-based ultrafiltration. Crude polyplexes were purified, with up to 60% of the initial PEI dose being removed. The resulting purified and unshielded PEI/DNA polyplexes are more efficient for transfection and less toxic to cells in culture than the crude ones. Moreover, the in vivo toxicity of the polyplexes was greatly reduced, without affecting their efficacy.     

Genuine DNA/polyethylenimine (PEI) complexes improve transfection properties and cell survival

Polyethylenimine (PEI) has been described as one of the most efficient cationic polymers for in vitro gene delivery. Systemic delivery of PEI/DNA polyplexes leads to a lung-expression tropism. Selective in vivo gene transfer would require targeting and stealth particles. Here, we describe two strategies for chemically coupling polyethylene glycol (PEG) to PEI, to form protected ligand-bearing particles. Pre-grafted PEG-PEI polymers lost their DNA condensing property, hence their poor performances. Coupling PEG to pre-formed PEI/DNA particles led to the expected physical properties. However, low transfection efficacies raised the question of the fate of excess free polymer in solution. We have developed a straightforward a purification assay, which uses centrifugation-based ultrafiltration. Crude polyplexes were purified, with up to 60% of the initial PEI dose being removed. The resulting purified and unshielded PEI/DNA polyplexes are more efficient for transfection and less toxic to cells in culture than the crude ones. Moreover, the in vivo toxicity of the polyplexes was greatly reduced, without affecting their efficacy.     

Polyelectrolyte Nanoparticles Mediate Vascular Gene Delivery

PURPOSE: The purpose is to develop a non-viral gene delivery system that meets the requirements of colloidal stability of DNA complexes expressed in terms of no particle aggregation under physiologic conditions. The system should be used to transfect cardiovascular tissues. METHODS: We used a strategy based on the formation of polyelectrolyte nanoparticles by deposition of alternatively charged polyelectrolytes onto a DNA core. Polyelectrolytes were transfer RNA as well as the synthetic polyanion, polyvinyl sulfate (PVS), and the polycation polyethylenimine (PEI). The PEI/DNA complex formed the DNA core. RESULTS: We observed that the DNA is condensed by polycations and further packaged by association with a polyanion. These nanoparticles exhibited negative surface charge and low aggregation tendency. In vivo rat carotid artery experiments revealed high transfection efficiency, not only with the reporter gene but also with the gene encoding human urokinase plasminogen activator (Hu-uPA). Hu-uPA is one of the proteins involved in the recovery of the blood vessels after balloon catheter injury and therefore clinically relevant. CONCLUSIONS: A strategy for in vivo gene transfer is proposed that uses the incorporation of polyanions as RNA or PVS into PEI/DNA complexes in order to overcome colloidal instability and to generate a negative surface charge. The particles proved to be transfectionally active in vascular gene transfer.     

不同相对分子质量聚乙烯亚胺体外介导基因传递的研究

目的研究4种不同相对分子质量聚乙烯亚胺（PEI）作为非病毒基因载体体外介导基因传递的能力。方法采用四甲基噻唑蓝法（MTT法）测定了PEI对Hela细胞的毒性,利用琼脂糖凝胶电泳阻滞试验考察PEI与DNA的结合能力,测定PEI—DNA复合物的粒径和Zeta电位,以及考察转染率。结果PEI的细胞毒性与相对分子质量呈正相关,高相对分子质量PEI的细胞毒性远大于低相对分子质量PEI;高相对分子质量PEI在较低的N／P比时就能对DNA起到完全阻滞作用;低相对分子质量PEI与DNA形成的复合物粒径明显大于高相对分子质量的PEI;Zeta电位随着PEI相对分子质量的增大而增大,复合物的粒径和Zeta电位都与组成中的N／P比有关;相对分子质量为2000的PEI（PEI2K）在Hela细胞中的转染率最低,而相对分子质量为25000的PEI（PEI25K）的转染率最高。结论PEI的相对分子质量对其各项性能指标以及介导基因传递的能力都有较大影响。     

Carboxymethyl poly(L-histidine) as a new pH-sensitive polypeptide to enhance polyplex gene delivery

Carboxymethyl poly( l-histidine) (CM-PLH) as a new pH-sensitive polypeptide has enhanced polyplex gene delivery. Agarose gel retardation assay and zeta potential measurement proved that the anionic CM-PLH at physiological pH coated the PEI/DNA binary complexes. The resulting CM-PLH/PEI/DNA ternary complexes showed the gene expression value 300 times higher than that of the PEI/DNA binary complexes. These results suggest that the synergistic effect of the pH-sensitive imidazole groups at endosomal pH and the anionic carboxymethyl groups at physiological pH in the CM-PLH enhanced polyplex gene delivery.     

DNA delivery to the mitochondria sites using mitochondrial leader peptide conjugated polyethylenimine

Some genetic diseases are associated with the defects of the mitochondrial genome. Direct DNA delivery to the mitochondrial matrix has been suggested as an approach for mitochondrial gene therapy for these diseases. We hypothesized that a mitochondrial leader peptide (LP) conjugated polyethylenimine (PEI) could deliver DNA to the mitochondrial sites. PEI-LP was synthesized by the conjugation of LP to PEI using disulfide bond. The complex formation of PEI-LP with DNA was confirmed by a gel retardation assay. In this study, DNA was completely retarded at a 0.4/1 PEI-LP/DNA weight ratio. In vitro delivery tests into isolated mitochondria or living cells were performed with rhodamin-labeled DNA and PEI-LP. In vitro cell-free delivery assay with isolated mitochondria showed that PEI-LP/DNA complexes were localized at mitochondria sites. Furthermore, the PEL-LP/DNA complexes were localized at the mitochondrial sites in living cells. However, a control carrier, PEI, did not show this effect. In addition, MTT assay showed that PEI-LP showed lower cytotoxicity than PEI. These results suggest that PEI-LP can deliver DNA to the mitochondrial sites and may be useful for the development of mitochondrial gene therapy.     

Stabilized Nonviral Formulations for the Delivery of MCP-1 Gene into Cells of the Vasculoendothelial System

PURPOSE: The purpose of this study was to develop a stabilized non-viral gene transfer system for the efficient delivery and expression of monocyte chemoattractant protein 1 (MCP-1) gene in cells of the vasculoendothelial system. METHODS: Plasmid DNA was condensed with polyethylenimine (PEI), conjugates of PEI with polyethylene glycol (PEG), and PEI conjugates with the membrane-active peptide melittin. Surface charge and particle size of the resulting gene transfer particles were analyzed by laser light scattering. Reporter gene studies and toxicity assays were conducted on smooth muscle cells and endothelial cells of human, porcine, or rat origin. RESULTS: Nonviral gene carriers containing PEI and PEG were developed that could be produced in batches of several milligrams and conveniently stored as frozen samples. Incorporation of PEG into the transfection complex significantly reduced cellular toxicity. The cryoconserved gene transfer particles mediated high expression of luciferase, enhanced green fluorescent protein (EGFP), or secreted alkaline phosphatase reporter genes. Highest reporter gene expression was achieved with PEI polyplexes containing PEG and melittin. The gene for MCP-1 was efficiently delivered into target cells and resulted in expression of up to 125 ng/ml secreted bioactive MCP-1 protein per 50,000 cells. CONCLUSIONS: Gene carriers based on PEI and PEG display reduced toxicity, can be stored in frozen form without loss of biological activity, and can efficiently transfect cells of the vasculoendothelial system. Such gene carriers hold a potential for use in arterial gene transfer and local secretion of MCP-1 as trigger of therapeutic arteriogenesis in arterial occlusion diseases.     

DNA delivery to the mitochondria sites using mitochondrial leader peptide conjugated polyethylenimine

Some genetic diseases are associated with the defects of the mitochondrial genome. Direct DNA delivery to the mitochondrial matrix has been suggested as an approach for mitochondrial gene therapy for these diseases. We hypothesized that a mitochondrial leader peptide (LP) conjugated polyethylenimine (PEI) could deliver DNA to the mitochondrial sites. PEI-LP was synthesized by the conjugation of LP to PEI using disulfide bond. The complex formation of PEI-LP with DNA was confirmed by a gel retardation assay. In this study, DNA was completely retarded at a 0.4/1 PEI-LP/DNA weight ratio. In vitro delivery tests into isolated mitochondria or living cells were performed with rhodamin-labeled DNA and PEI-LP. In vitro cell-free delivery assay with isolated mitochondria showed that PEI-LP/DNA complexes were localized at mitochondria sites. Furthermore, the PEL-LP/DNA complexes were localized at the mitochondrial sites in living cells. However, a control carrier, PEI, did not show this effect. In addition, MTT assay showed that PEI-LP showed lower cytotoxicity than PEI. These results suggest that PEI-LP can deliver DNA to the mitochondrial sites and may be useful for the development of mitochondrial gene therapy.     

脂质体-聚乙烯亚胺-DNA三元复合物的构建及其对细胞的体外转染

目的研究非病毒基因载体脂质体-聚乙烯亚胺(PEI)-DNA三元复合物(TC)的制备方法,评价其体外细胞学性质。方法采用乙醇注入法制备空白阴离子脂质体,与PEI/DNA复合物37℃孵育30 min后,得到TC,考察其理化性质、抗核酸酶降解能力、血浆稳定性、细胞毒性及在卵巢癌细胞(Hela)中的转染效率。结果制备的TC呈类球形,大小较均匀,平均粒径为234.5 nm,Zeta电位为-20.72 mV;TC能在血浆中稳定存在4 h而不发生聚集;与核酸酶作用2 h后,其中的DNA几乎无降解;其细胞毒性较低,在无血清和含血清培养基中均能成功的转染Hela细胞,在含血清培养基中其转染效率明显高于PEI/DNA复合物。结论 TC是一种制备工艺简单、血浆稳定性好、转染率较高、极具应用潜力的非病毒纳米基因载体。     

Silica-Iron Oxide Magnetic Nanoparticles Modified for Gene Delivery: A Search for Optimum and Quantitative Criteria

Purpose

To optimize silica-iron oxide magnetic nanoparticles with surface phosphonate groups decorated with 25-kD branched polyethylenimine (PEI) for gene delivery.

Methods

Surface composition, charge, colloidal stabilities, associations with adenovirus, magneto-tranduction efficiencies, cell internalizations, in vitro toxicities and MRI relaxivities were tested for the particles decorated with varying amounts of PEI.

Results

Moderate PEI-decoration of MNPs results in charge reversal and destabilization. Analysis of space and time resolved concentration changes during centrifugation clearly revealed that at >5% PEI loading flocculation gradually decreases and sufficient stabilization is achieved at >10%. The association with adenovirus occurred efficiently at levels over 5% PEI, resulting in the complexes stable in 50% FCS at a PEI-to-iron w/w ratio of ??7%; the maximum magneto-transduction efficiency was achieved at 9?C12% PEI. Primary silica iron oxide nanoparticles and those with 11.5% PEI demonstrated excellent r₂* relaxivity values (>600?s^?1(mM Fe)^?1) for the free and cell-internalized particles.

Conclusions

Surface decoration of the silica-iron oxide nanoparticles with a PEI-to-iron w/w ratio of 10-12% yields stable aqueous suspensions, allows for efficient viral gene delivery and labeled cell detection by MRI.     

Anti-Inflammatory Therapeutic Effect of Adiponectin Gene Delivery Using a Polymeric Carrier in an Acute Lung Injury Model

Purpose

Adiponectin (APN) is an adipokine with anti-inflammatory and cytoprotective effects. In this study, the therapeutic effect of APN gene delivery using a polymeric carrier was evaluated in an acute lung injury (ALI) model.

Methods

Polyethylenimine (2 kDa, PEI2K), PEI25K (25 kDa), polyamidoamine (generation 2, PAMG2), dexamethasone-conjugated PEI2k (PEI2K-Dexa), and dexamethasone-conjugated PAMG2 (PAMG2-Dexa) were evaluated in vitro and in vivo as gene carriers. Formation of plasmid DNA (pDNA)/carrier complexes was confirmed by gel retardation and heparin competition assays. Delivery efficiency was measured by a luciferase assay and fluorescence microscopy. In an ALI animal model, pAPN/carrier complexes were delivered by intratracheal administration. Therapeutic effects were evaluated by cytokine assays and hematoxylin and eosin (H&E) staining.

Results

Gel retardation assays showed that PEI2K-Dexa and PAMG2-Dexa formed complexes with pDNA. In L2 lung epithelial cells, PAMG2-Dexa yielded higher transfection efficiency than PEI2K, PAMG2, PEI25K, lipofectamine, and PEI2K-Dexa. In vivo experiments showed that PAMG2-Dexa delivered DNA more efficiently to lung tissue than PEI2K-Dexa and PEI25K. Delivery of pAPN/PAMG2-Dexa complexes upregulated APN expression in the lungs of mice with ALI. As a result, the levels of pro-inflammatory cytokines such as TNF-α and IL-1β were decreased. H&E staining showed that inflammation in the lungs of mice with ALI was reduced by delivery of the APN gene.

Conclusion

Delivery of the APN gene using PAMG2-Dexa reduced inflammation in the lungs of mice with ALI. The APN gene could be a useful tool in the development of gene therapy for ALI.

     

Receptor-targeted gene delivery viafolate-conjugated polyethylenimine

A novel synthetic gene transfer vector was evaluated for tumor cell-specific targeted gene delivery. The folate receptor is a tumor marker overexpressed in more than 90% of ovarian carcinomas and large percentages of other human tumors. Folic acid is a high affinity ligand for the folate receptor that retains its binding affinity upon derivatization via its gamma carboxyl. Folate conjugation, therefore, presents a potential strategy for tumor-selective targeted gene delivery. In the current study, we investigated a series of folate conjugates of the cationic polymer polyethylenimine (PEI) for potential use in gene delivery. A plasmid containing a luciferase reporter gene (pCMV-Luc) and the folate receptor expressing human oral cancer KB cells were used to monitor gene transfer efficiency in vitro. Transfection activity of polyplexes containing unmodified polyethylenimine was highly dependent on the positive to negative charge (or the N/P) ratio. Folate directly attached to PEI did not significantly alter the transfection activity of its DNA complexes compared to unmodified PEI. Modification of PEI by polyethyleneglycol (PEG) led to a partial inhibition of gene delivery compared to unmodified PEI. Attaching folates to the distal termini of PEG-modified PEI greatly enhanced the transfection activity of the corresponding DNA complexes over the polyplexes containing PEG-modified PEI. The enhancements were observed at all N/P ratios tested and could be blocked partially by co-incubation with 200 μM free folic acid, which suggested the involvement of folate receptor in gene transfer. Targeted vectors based on the folate-PEG-PEI conjugate are potentially useful as simple tumor-specific vehicles of therapeutic genes.     

A one-step process in preparation of cationic nanoparticles with poly(lactide-co-glycolide)-containing polyethylenimine gives efficient gene delivery

A one-step preparation of nanoparticles with poly(lactide-co-glycolide) (PLGA) pre-modified with polyethylenimine (PEI) is better in requirements for DNA delivery compared to those prepared in a two-step process (preformed PLGA nanoparticles and subsequently coated with PEI). The particles were prepared by emulsification of PLGA/ethyl acetate in an aqueous solution of PVA and PEI. DLS, AFM and SEM were used for the size characteristics. The cytotoxicity of PLGA/PEI nanoparticles was detected by MTT assay. The transfection activity of the particles was measured using pEGFP and pβ-gal plasmid DNA. Results showed that the PLGA/PEI nanoparticles were spherical and non-porous with a size of about 0.2 μm and a small size distribution. These particles had a positive zeta potential demonstrating that PEI was attached. Interestingly, the zeta potential of the particles (from one-step procedure) was substantially higher than that of two-step process and is ascribed to the conjugation of PEI to PLGA via aminolysis. The PLGA/PEI nanoparticles were able to bind DNA and the formed complexes had a substantially lower cytotoxicity and a higher transfection activity than PEI polyplexes. In conclusion, given their small size, stability, low cytotoxicity and good transfection activity, PLGA/PEI-DNA complexes are attractive gene delivery systems.     

Optimized dextran-polyethylenimine conjugates are efficient non-viral vectors with reduced cytotoxicity when used in serum containing environments

Polyethylenimine (PEI) is a cationic polymer that is an efficient transfection reagent marred by high toxicity and a susceptibility to aggregate in the presence of serum. Dextran is a biodegradable natural polysaccharide that can be used to reduce the toxicity of PEI and increase its stability in the presence of serum. In this study, small branched PEI units (800/2000 Da) were attached to dextran (Dex; 15/100-200 kDa) to form dextran-polyethylenimine (Dex-PEI) conjugates. The Dex-PEI conjugates were then tested as a gene carrier in the model HEK293 cell line. Dex-PEI conjugates displayed significantly lower cytotoxicity than PEI (25k). Both Dex-PEI and PEI efficiently delivered firefly luciferase encoded plasmid DNA (pDNA) to the HEK293 cells. Dex-PEI resulted in moderately lower transfection efficiencies than PEI 25k when the transfection was carried out in media without serum for 4h. However, in the presence of serum, which more accurately predicts the anticipated environment of non-viral vectors in vivo, Dex-PEI and unmodified PEI generated similar transfection efficiencies when incubated with the cells for 4h. When the incubation time of the vectors was increased to 48h, significantly higher transfection efficiencies were generated by Dex-PEI in comparison to PEI. Turbidity measurements showed that complexes formed between plasmid DNA and unmodified PEI were more susceptible to aggregation in serum-containing media than complexes formed from pDNA and Dex-PEI. Dex-PEI conjugates are therefore believed to have greater potential for translational applications because of lower cytotoxicity characteristics and improved stability in serum containing environments.     

Efficient in vivo gene transfection by stable DNA/PEI complexes coated by hyaluronic acid

Plasmid DNA was mixed with polyethyleneimine (PEI) and hyaluronic acid (HA) to afford ternary complexes with negative surface charge regardless of the mixing order. They showed reduced non-specific interactions with blood components. When DNA and PEI were mixed at a high concentration such as that used in in vivo experiments, they soon aggregated, and large particles were formed. On the other hand, pre-addition of HA to DNA prior to PEI effectively diminished the aggregation, and 10% (in volume) of the complexes remained as small particles with a diameter below 80 nm. Those negatively charged small ternary complexes induced a much stronger extra-gene expression in tumor than binary DNA/PEI complex after intratumoral or intravenous injection into the mice bearing B16 cells.     

Aerosol delivery of spermine-based poly(amino ester)/Akt1 shRNA complexes for lung cancer gene therapy

Polyethylenimine (PEI) has been commonly used as a cationic polymeric gene carrier due to high transfection efficiency, however, its cytotoxicity has hindered the practical application. In this study, we report the development of poly(amino ester) (PAE) based on glycerol propoxylate triacrylate (GPT) and spermine (SPE) as an alternative gene carrier for lung cancer therapy. GPT-SPE copolymer was prepared by Michael addition reaction between GPT and SPE, and the efficacy was evaluated using shAkt1 as a model therapeutic gene. The molecular weight and composition were characterized using gel permeability chromatography (GPC) and ¹H-nuclear magnetic resonance (¹H-NMR), respectively. The GPT-SPE could effectively condense DNA with about 163 nm size and protect the DNA from nucleases. GPT-SPE/DNA complexes showed excellent transfection with low toxicity both in vitro and in vivo. Furthermore, aerosol delivery of GPT-SPE/Akt1 shRNA complexes significantly suppressed lung tumorigenesis in K-ras^LA1 lung cancer model mice. These results suggest that GPT-SPE can be used in shRNA-based lung cancer gene therapy.     

Gene delivery system of pDNA using the blood glycoprotein fetuin

Fetuin is a biocompatible plasma protein and strongly enhances phagocytosis of bacteria, DNA and apoptotic cells by peripheral blood cells such as monocytes, macrophages and dendritic cells. We developed a novel gene delivery system: ternary complexes constructed with pDNA, polyethylenimine (PEI) and fetuin. Without covalent binding, fetuin was able to coat pDNA–PEI complexes, and stable anionic nanoparticles formed at a weight ratio greater than 30. Optimised pDNA–PEI–fetuin complexes significantly decreased the cytotoxicity of pDNA–PEI complexes in the melanoma cell line B16F10. Furthermore, the pDNA–PEI–fetuin complexes had higher transgene efficiency compared to that of commercial lipofectin previously reported in B16F10 cells despite an anionic surface. The pDNA–PEI–fetuin complexes did not agglutinate with erythrocytes. The pDNA–PEI–fetuin complexes had high gene expression in the spleen after intravenous administration in mice. Thus, the pDNA–PEI–fetuin complexes were a useful in vivo gene delivery system with tropism for the spleen.     

Fabrication of a Novel Core-Shell Gene Delivery System Based on a Brush-Like Polycation of α, β–Poly (L-Aspartate-Graft-PEI)

Purpose  A novel core-shell gene delivery system was fabricated in order to improve its gene transfection efficiency, particularly in the presence of serum. Materials and Methods  α, β–poly (L-aspartate-graft-PEI) (PAE) was simply synthesized by ring-opening reaction of poly (L-succinimide) with low molecular weight (LMW) linear polyethylenimine (PEI, Mn = 423). PAE/DNA nanoparticles were characterized. Condensation and protection ability of plasmid by PAE were confirmed by agarose gel electrophoresis assay. Cytotoxicity of the polymer and polymer/DNA nanoparticles were measured by MTS assay. Gene transfection efficiencies were evaluated both in vitro and in vivo. Results  Core-shell nanoparticles assembled between DNA and PAE showed positive zeta potential, narrow size distribution, and spherical compact shapes with size below 250 nm when N/P ratio is above 10. Cytotoxicity of PAE was rather lower than that of PEI 25K, while the most efficient gene transfection and serum resistant ability of PAE/DNA complexes were higher than that of PEI 25K. Bafilomycin A1 treatment suggested “proton sponge” mechanism of PAE-mediated gene transfection. PAE/pEGFP-N2 nanoparticles also showed good gene expression in vivo and were dominantly distributed in kidney, liver, spleen and lung after intravenous administration. Conclusions  The results demonstrated the potential use of PAE as an effective gene carrier. J.-H. Yu and J.-S. Quan have contributed equally to this work.     

Polyethylenimine–DNA solid particles for gene delivery

Polyethylenimine (PEI), a cationic polymer, was used to develop a non-viral vector for gene delivery. A simple, reproducible process is described with which to condense plasmid DNA with PEI. When prepared at the optimum charge ratio of 6.3 ( ± ; PEI:DNA, 5:1 w/w), PEI–DNA complexes were 30–60 nm in diameter and excluded intercalating dyes from the plasmid DNA. The particles were stable for more than one month at 4°C with respect to size and transfection activity. PEI–condensed DNA transfected a broad range of murine and human tumor cell lines (B16, Lewis Lung, SK-OV-3 and LS180) in vitro in the presence of fetal calf serum. Intraperitoneal administration of PEI–condensed DNA resulted in significant gene expression in a human ovarian cancer peritoneal xenograft model.