Polycation liposome-mediated gene transfer in vivo

The polycation liposome (PCL), a recently developed gene transfer system, is simply prepared by a modification of liposomes with cetylated polyethylenimine (PEI), and shows remarkable transgene efficiency with low cytotoxicity. In the present study, we investigated the applicability of PCLs for in vivo gene transfer, since the PCL-mediated transgene efficiency was found to be maintained in the presence of serum. PCLs composed of dioleoylphosphatidylethanolamine (DOPE) with 5 mol% cetyl PEI (PEI average mr. wt. 1800), were superior for transfection to those of dipalmitoylphosphatidylcholine (DPPC) and cholesterol (2:1 as molar ratio) with 5 mol% cetyl PEI in vitro, although the latter PCLs were more efficient for gene transfer in vivo. PCL-DNA complexes were injected into mice via a tail or the portal vein, with the DNA being a plasmid encoding green fluorescent protein (GFP) or luciferase; and the expression was monitored qualitatively or quantitatively, respectively. Tail vein injection resulted in high expression of both GFP and luciferase genes in lung, and portal vein injection resulted in high expression of both genes in the liver. Concerning the gene delivery efficiency, the PCL was found to be superior to PEI or cetyl PEI alone. The optimal conditions for in vivo transfection with PCLs were also examined.     

Polycation liposome-mediated gene transfer in vivo

The polycation liposome (PCL), a recently developed gene transfer system, is simply prepared by a modification of liposomes with cetylated polyethylenimine (PEI), and shows remarkable transgene efficiency with low cytotoxicity. In the present study, we investigated the applicability of PCLs for in vivo gene transfer, since the PCL-mediated transgene efficiency was found to be maintained in the presence of serum. PCLs composed of dioleoylphosphatidylethanolamine (DOPE) with 5 mol% cetyl PEI (PEI average mr. wt. 1800), were superior for transfection to those of dipalmitoylphosphatidylcholine (DPPC) and cholesterol (2:1 as molar ratio) with 5 mol% cetyl PEI in vitro, although the latter PCLs were more efficient for gene transfer in vivo. PCL-DNA complexes were injected into mice via a tail or the portal vein, with the DNA being a plasmid encoding green fluorescent protein (GFP) or luciferase; and the expression was monitored qualitatively or quantitatively, respectively. Tail vein injection resulted in high expression of both GFP and luciferase genes in lung, and portal vein injection resulted in high expression of both genes in the liver. Concerning the gene delivery efficiency, the PCL was found to be superior to PEI or cetyl PEI alone. The optimal conditions for in vivo transfection with PCLs were also examined.     

Enhanced delivery of naked DNA to the skin by non-invasive in vivo electroporation

DNA delivery to skin may be useful for the treatment of skin diseases, DNA vaccinations, and other gene therapy applications requiring local or systemic distribution of a transgene product. However, the effective, consistent and patient-friendly transfection of skin cells remains a challenge. In a mouse model, we evaluated the effectiveness of intradermal injection of plasmid DNA followed by noninvasive in vivo electroporation (EP) as a method to improve transfection in skin. We achieved a several hundred-fold stimulation of gene expression by EP, sufficient to produce clinically relevant amounts of transgene product. We studied the effect of DNA dose and time after treatment as well as various EP pulse parameters on the efficiency of gene expression. EP under conditions of constant charge transfer revealed that the applied voltage was the main determinant for transgene expression efficiency while other pulse parameters had lesser effects. Patient-friendly, noninvasive meander electrodes which we designed for clinical applications proved equally effective and safe as plate electrodes. We also showed for the first time that noninvasive EP is effective in stimulating transfection and gene expression in human skin, particularly in the epidermis. Our findings demonstrate the applicability of EP-enhanced DNA delivery to skin for gene therapy, DNA immunization and other areas.     

Application of the Sleeping Beauty system in Saanen goat fibroblast cells for establishing persistent transgene expression

The Sleeping Beauty (SB) transposon system is a promising new method for establishing persistent transgene expression in vivo. We applied the SB system for enhancing transgenesis in Saanen dairy goat fibroblast cells. We constructed a pKT2/CMV-EGFP-IRES-PURO vector and investigated the influence of transposon and transposase vector ratios on transfection efficiency in the Saanen goat fibroblast cells. To enhance the SB system performance, we developed a new transfection technique (double-transfection method) for the SB system. The cultured cells were transfected with transposase and transposon vectors successively, with a 42-h interval. Consequently, the transposase and DNA donor (transposon vector) can interact, both at the highest level. Compared with the traditional transfection method, this new double-transfection method approximately doubled integration efficiency.     

Reexamination of the effect of endotoxin on cell proliferation and transfection efficiency

Plasmid DNA purified from bacterial cells can be contaminated with endotoxin to different extents, depending on the purification method. Earlier reports indicate that endotoxin can decrease transfection efficiency in many eukaryotic cell lines; however, the amount of endotoxin required for inhibition is unclear. We determined endotoxin effects in several cell lines and observed that endotoxin levels greater than or equal to 10,000 endotoxin units (EU) were needed to significantly affect cell proliferation and viability; levels greater than 2000 EU/mu g DNA were required to significantly inhibit transfection for all but one (Huh-7) of the cell lines tested. These endotoxin levels are significantly higher than endotoxin contamination in plasmid DNA purified by anion exchange, CsCl2 gradient and endotoxin-free purification technology, but not as high as a crude alkaline lysis preparatory method. Plasmid DNA prepared using anion exchange technology was comparable to endotoxin-free technology in terms of transfection efficiency. Even Huh-7 cells, which are markedly more sensitive to endotoxins, have comparable transfection efficiencies using plasmid DNA purified by either of these two methods. We conclude that for those cell lines commonly used for transfection studies, endotoxin-free, quality DNA is not necessary because significantly higher levels of bacterial endotoxins are required to inhibit either cell proliferation or transfection.     

Nonviral vector-based gene transfection of primary human skeletal myoblasts

Low-level transgene efficiency is one of the main obstacles in ex vivo nonviral vector-mediated gene transfer into primary human skeletal myoblasts (hSkMs). We optimized the cholesterol:N-[1-(2, 3-dioleoyloxy)propyl]-N, N, N-trimethylammonium methylsulfate liposome (CD liposome) and 22-kDa polyethylenimine (PEI22)- and 25-kDa polyethylenimine (PEI25)-mediated transfection of primary hSkMs for angiogenic gene delivery. We found that transfection efficiency and cell viability of three nonviral vectors were cell passage dependent: early cell passages of hSkMs had higher transfection efficiencies with poor cell viabilities, whereas later cell passages of hSkMs had lower transfection efficiencies with better cell viabilities. Trypsinization improved the transfection efficiency by 20% to 60% compared with adherent hSkMs. Optimum gene transfection efficiency was found with passage 6 trypsinized hSkMs: transfection efficiency with CD lipoplexes was 6.99 +/- 0.13%, PEI22 polyplexes was 18.58 +/- 1.57%, and PEI25 polyplexes was 13.32 +/- 0.88%. When pEGFP (a plasmid encoding the enhanced green fluorescent protein) was replaced with a vector containing human vascular endothelial growth factor 165 (phVEGF(165)), the optimized gene transfection conditions resulted in hVEGF(165) expression up to Day 18 with a peak level at Day 2 after transfection. This study demonstrated that therapeutic angiogenic gene transfer through CD or PEI is feasible and safe after optimization. It could be a potential strategy for treatment of ischemic disease for angiomyogenesis.     

Free radical-mediated transgene inactivation of macrophages by endotoxin

Endotoxin, the lipopolysaccharide component of gram-negative bacteria, is a common contaminant of plasmid DNA preparations. The present study investigated the effect of endotoxin on gene transfection efficiency and the role of reactive oxygen species (ROS) in this process. Gene transfection studies were performed in various cell types with cytomegalovirus-luciferase as a reporter plasmid and cationic liposome as a transfecting agent. The presence of endotoxin in plasmid DNA preparations severely limited transgene expression in macrophages but had little or no effect in other cell types tested. This decreased transfection was dependent on ROS-mediated cellular toxicity induced by endotoxin. Neutralizing the endotoxin by the addition of polymyxin B effectively increased transfection efficiency and reduced toxicity. Electron spin resonance studies confirmed the formation of ROS in endotoxin-treated cells and their inhibition by free radical scavengers. The ROS scavenger N-t-butyl-alpha-phenylnitrone, the H(2)O(2) scavenger catalase, and the.OH scavenger sodium formate effectively inhibited endotoxin-induced effects, whereas the O(2)(-) scavenger superoxide dismutase had lesser effects. These results indicate that multiple oxidative species are involved in the transfection inactivation process and that.OH formed by H(2)O(2)-dependent, metal-catalyzed Fenton reaction play a major role in this process.     

Trehalose enhances transgene expression mediated by DNA-PEI complexes

Using enhancers to improve the transfection efficiency of polyethylenimine (PEI) can circumvent the needs of chemical modifications as well as subsequent purification and characterization of the modified PEI. In this study, we found that incorporating trehalose into the transfection reagent could improve the transgene expression mediated by DNA-PEI complexes. Such enhancements were not observed when trehalose was replaced by other disaccharides. In an effort to explore the mechanisms, we examined how the timing of trehalose treatments and the durations of trehalose affected the percentages of cells expressing green fluorescent protein and the levels of intracellular ethidium monoazide labeled plasmid. Treatments with trehalose for 5-120 min prior to transfection could cause drops in transfection efficiency by 30-50%; such treatments, however, hardly affected the amounts of intracellular plasmid, indicating that the preexistence of intracellular trehalose could reduce transfection efficiency without lowering the endocytic activity. The transfection efficiency remained almost unchanged when the transfected cells were treated with trehalose after the removal of transfection reagents, indicating that trehalose had minimal effects on the machinery of protein synthesis. Despite the enhanced transgene expression, the presence of trehalose during transfection showed inhibitory effects on the internalization of DNA-PEI complexes. Additionally, the extent of enhancement in transgene expression strongly depended on the duration of trehalose. As the above observations suggested, only during the transfection process when complexes and trehalose coexisted, trehalose became an effective enhancer of transgene expression mediated by DNA-PEI complexes possibly by affecting the mechanisms of intracellular trafficking.     

CFTR transgene expression in primary DeltaF508 epithelial cell cultures from human nasal polyps following gene transfer with cationic phosphonolipids

Cystic fibrosis (CF) is the most common autosomal lethal recessive disorder in the Caucasian population. The major cause of mortality is lung disease, owing to the failure of a functional protein from the cystic fibrosis transmembrane conductance regulator (CFTR) gene. Today, even though the knowledge about the CFTR genomic is extensive, no efficient treatment has been developed yet. In this context, gene therapy represents a potential important advance on condition that it could develop efficient and safe transfection agents. Even though viral vectors have been used in most clinical trials owing to their high transfection efficiency, random integration and immunogenicity are still critical side effects. Consequently, all of these drawbacks brought forth the development of nonviral transfection systems. Although they engender few toxicity and immunogenicity problems, their low transfection efficiency is a hurdle that must be overcome. Over the past decade, we have developed an original family of monocationic lipids, cationic phosphonolipids, whose efficiency has been previously demonstrated both in vitro and in vivo. In this report, we observe that a new cationic phosphonolipid (KLN 30) can lead to the restoration of the CFTR protein following the ex vivo transfection of epithelial cells issuing from a F508 homozygous patient. The transgene expression and the cytotoxicity correlate with the charge ratio of the lipoplex. A kinetic study was performed, and a luminescent signal was detected until 35 d after transfection.     

CFTR transgene expression in primary ΔF508 epithelial cell cultures from human nasal polyps following gene transfer with cationic phosphonolipids

Cystic fibrosis (CF) is the most common autosomal lethal recessive disorder in the Caucasian population. The major cause of mortality is lung disease, owing to the failure of a functional protein from the cystic fibrosis transmembrane conductance regulator (CFTR) gene. Today, even though the knowledge about the CFTR genomic is extensive, no efficient treatment has been developed yet. In this context, gene therapy represents a potential important advance on condition that it could develop efficient and safe transfection agents. Even though viral vectors have been used in most clinical trials owing to their high transfection efficiency, random integration and immunogenicity are still critical side effects. Consequently, all of these drawbacks brought forth the development of nonviral transfection systems. Although they engender few toxicity and immunogenicity problems, their low transfection efficiency is a hurdle that must be overcome. Over the past decade, we have developed an original family of monocationic lipids, cationic phosphonolipids, whose efficiency has been previously demonstrated both in vitro and in vivo. In this report, we observe that a new cationic phosphonolipid (KLN 30) can lead to the restoration of the CFTR protein following the ex vivo transfection of epithelial cells issuing from a ΔF508 homozygous patient. The transgene expression and the cytotoxicity correlate with the charge ratio of the lipoplex. A kinetic study was performed, and a luminescent signal was detected until 35 d after transfection.     

Tris[2-(acryloyloxy)ethyl]isocyanurate cross-linked low-molecular-weight polyethylenimine as gene delivery carriers in cell culture and dystrophic mdx mice

Hyperbranched poly(ester amine)s (PEAs) were successfully synthesized by Michael addition reaction between tris[2-(acryloyloxy)ethyl]isocyanurate (TAEI) and low-molecular-weight polyethylenimine (LPEI, M(w) 0.8k, 1.2k, and 2.0k) and evaluated in vitro and in vivo as gene carriers. PEAs effectively condensed plasmid DNA with particle sizes below 200 nm and surface charges between 11.5 and 33.5 mV under tested doses [at the ratios 2-10:1 of polymer/pDNA(w/w)]. The PEAs showed significantly lower cytotoxicities when compared with PEI 25k in two different cell lines. The PEAs (C series) composed of PEI 2k showed higher transgene expression compared to PEAs of PEI 0.8k (A series) or 1.2k (B series). Highest gene transfection efficiency in CHO, C2C12 myoblast, and human skeletal muscle (HSK) cell lines was obtained with TAEI/PEI-2K (C12) at a ratio of 1:2. Both C12, C14(TAEI/PEI-2K at a ratio of 1:4) demonstrated 5-8-fold higher gene expression as compared with PEI 25k in mdx mice in vivo through intramuscular administration. No obvious muscle damage was observed with these new polymers. Higher transfection efficiency and lower toxicity indicate the potential of the biodegradable PEAs as safe and efficient transgene delivery vectors.     

Optimization of in vitro vascular cell transfection with non-viral vectors for in vivo applications

BACKGROUND: Syngeneic vascular cells are interesting tools for indirect gene therapy in the cardiovascular system. This study aims to optimize transfection conditions of primary cultures of vascular smooth muscle cells (VSMCs) using different non-viral vectors and zinc as an adjuvant and to implant these transfected cells in vivo. METHODS: Non-liposomal cationic vectors (FuGene 6), polyethylenimines (ExGen 500), and histidylated polylysine (HPL) were used as non-viral vectors in vitro with secreted alkaline phosphatase (SEAP) as reporter gene. Transfection efficiency was compared in cultured rat, rabbit and human VSMCs and fibroblasts. Zinc chloride (ZnCl2) was added to optimize transfection of rat VSMCs in vitro which were then seeded in vivo. RESULTS: Much higher SEAP levels were obtained in rabbit cells with FuGene 6 (p <0.0001) at day 2 than in equivalent rat and human cells. Rat VSMCs transfected in vitro with FuGene 6 and ExGen 500 expressed higher SEAP levels than with HPL. In rat VSMCs, SEAP secretion was more than doubled by addition of 250 microM ZnCl2 (p <0.0001) for all vectors. Seeding of syngeneic VSMCs transfected under optimized conditions (FuGene 6/pcDNA3-SEAP +250 microM ZnCl2) into healthy Lewis rats using various routes or into post-infarct myocardial scar resulted in a peak of SEAP expression at day 2 and detectable activity in the plasma for at least 8 days. CONCLUSIONS: FuGene 6 is an efficient non-viral transfection reagent for gene transfer in somatic smooth muscle cells in vitro and ZnCl2 enhances its efficiency. This increased expression of the transgene product is maintained after seeding in vivo.     

DNA nanoparticles: detection of long-term transgene activity in brain using bioluminescence imaging

In this study, we used bioluminescence imaging (BLI) to track long-term transgene activity following the transfection of brain cells using a nonviral gene therapy technique. Formulations of deoxyribonucleic acid (DNA) combined with 30-mer lysine polymers (substituted with 10 kDa polyethylene glycol) form nanoparticles that transfect brain cells in vivo and produce transgene activity. Here we show that a single intracerebral injection of these DNA nanoparticles (DNPs) into the rat cortex, striatum, or substantia nigra results in long-term and persistent luciferase transgene activity over an 8- to 11-week period as evaluated by in vivo BLI analysis, and single injections of DNPs into the mouse striatum showed stable luciferase transgene activity for 1 year. Compacted DNPs produced in vivo signals 7- to 34-fold higher than DNA alone. In contrast, ex vivo BLI analysis, which is subject to less signal quenching from surrounding tissues, demonstrated a DNP to DNA alone ratio of 76- to 280-fold. Moreover, the ex vivo BLI analysis confirmed that signals originated from the targeted brain structures. In summary, BLI permits serial analysis of luciferase transgene activity at multiple brain locations following gene transfer with DNPs. Ex vivo analysis may permit more accurate determination of relative activities of gene transfer vectors.     

Lipopolysaccharide recognition protein, MD-2, facilitates cellular uptake of E. coli-derived plasmid DNA in synovium

BACKGROUND: Several cell types are susceptible to transfection in vivo using naked plasmid DNA. The mechanisms involved in mediating in vivo transfection are incompletely known, but evidence suggests that receptor-mediated endocytosis is important for specific types of cells. In this study we tested the hypothesis that residual Escherichia coli lipopolysaccharide (LPS) forms a non-covalent complex with expression plasmid DNA, and host-cell-derived soluble LPS-binding proteins bind to the DNA-LPS complexes in order to facilitate receptor-mediated endocytosis. METHODS: Cells from the murine synovial lining were used as an in vivo model system and in vivo luciferase imaging was used to quantify levels of transgene expression. Using a series of gene-deleted mice, the roles of LPS recognition complex proteins, lipopolysaccharide-binding protein (LBP), CD14 and MD-2, in the process of in vivo transfection were determined. RESULTS: Luciferase expression assays revealed that mice lacking LBP or CD14 had increased luciferase expression (p < 0.023 and < 0.165, respectively), while mice deleted of MD-2 had significant reductions in luciferase expression (p < 0.001). Gene deletion of hyaluronic acid binding protein CD44 was used as a control and had no statistically significant effect on transgene expression in vivo. In muscle tissue, where neither cell surface nor soluble MD-2 is expressed, no MD-2 dependence of plasmid transfection was identified, suggesting the role of MD-2 is tissue or cell type specific. Additionally, depleting mice of macrophages showed that luciferase expression is occurring within fibroblast-like synoviocytes. CONCLUSIONS: Our data support a physical association between LPS and E. coli-derived plasmid DNA, and that in vivo transfection of fibroblast-like synoviocytes is dependent on the soluble form of the LPS-binding protein MD-2.     

阳离子脂质体转染人类骨骼肌原代细胞的初步研究

探讨不同脂质体介导基因转染人类骨骼肌原代细胞的转染效率和基因的表达.将含有β-半乳糖苷酶LacZ结构基因的质粒,用三种不同的阳离子脂质体导入人类骨骼肌原代细胞中,通过X-Gal染色观察不同的转染效率.结果发现,Fugene 6转染效率最高,蓝染细胞达10%,其脂质体与DNA的最佳比例为3∶ 2.Fugene 6可有效地将外源基因导入骨骼肌原代细胞,而且外源基因可以长效高效地表达,有望用来作为基因治疗的载体.     

Improved non-viral transfection of glial and adult neural stem cell lines and of primary astrocytes by combining agents with complementary modes of action

BACKGROUND: Rational design of gene vectors for therapeutic applications requires understanding of transfection mechanisms. In this study, multiple transfection assays revealed complementary mechanisms between two commonly used transfection agents. This finding was then exploited to produce improved transfection outcomes. METHODS AND RESULTS: Rat C6 glial cells, adult rat hippocampal progenitor cells and primary astrocytes were transfected using Lipofectamine (LA) or polyethylenimine (PEI), in vitro. Although LA- and PEI-transfected populations expressed the same total level of transgene product, LA transfected considerably more cells than PEI (approximately 20 vs. 14%). A fluorescently labelled plasmid and time-course analysis, involving both flow cytometry and confocal microscopy, were used to explain this apparent discrepancy. Results showed that LA delivered more plasmid DNA to the cytoplasm and achieved transgene expression in more cells than PEI. In contrast, PEI transfected fewer cells but, on average, produced more transgene product per transfected cell. CONCLUSIONS: A comparative transfection model was developed to explain these different characteristics. According to this model, transfection is a multistage process with different transfection agents exerting their primary effect at different stages in this process. This model forecast that it should be possible to prepare a chimeric complex with a transfection efficiency that exceeded that achievable with Lipofectamine or polyethylenimine alone. This prediction was tested and shown to hold for glioma cells, primary astrocytes, and adult neural stems cells.