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.     

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.     

Receptor-mediated, tumor-targeted gene delivery using folate-terminated polyrotaxanes

Safe and effective gene delivery is essential to the success of gene therapy. We synthesized and characterized a novel nonviral gene delivery system in which folate (FA) molecules were functioned as blockers on cationic polyrotaxanes (PR) composed of poly(ethylenimine) (PEI)(600)-grafted α-cyclodextrin rings linearized on polyethylene glycol to form FA-terminated PR-PEI(600) (FPP). The FA terminal caps of FPP target cell surfaces abundant in FA receptor (FR), a common feature of tumor cells. The structure of FPP was characterized by using (1)H nuclear magnetic resonance ((1)H NMR). The delivery particle was composed of chemically bonded PEG (4000), α-cyclodextrins (CD), and PEI (600 Da) at a molar ratio of 1:17:86.7, and the particle size and zeta potential of FPP/pDNA polyplexes were measured using dynamic light scattering. FPP/pDNA exhibited a lower cytotoxicity, strong specificity to FR, and high efficiency of delivering DNA to target cells in vitro and in vivo with the reporter genes. Furthermore, the FPP/DNA complex showed an enhanced antitumor effect in the nude mice compared with other delivery systems, such as PEI-25K. Together, these results suggest that FPP may be useful for gene therapy.     

Efficient serum-resistant lipopolyplexes targeted to the folate receptor

In this work, we have developed and evaluated a new targeted lipopolyplex (LPP), by combining polyethylenimine (PEI), 1,2-dioleoyl-3-(trimethylammonium) propane (DOTAP)/Chol liposomes, the plasmids pCMVLuc/pCMVIL-12, and the ligand folic acid (FA), able to transfect HeLa and B16-F10 cells in the presence of very high concentration of serum (60% FBS). These complexes (Fol-LPP) have a net positive surface charge. The combination of folic acid with lipopolyplexes also enhanced significantly the transfection activity of the therapeutic gene interleukin-12 (IL-12), without any significant cytotoxicity. The specificity of the folate receptor (FR)-mediated gene transfer was corroborated by employing a folate receptor deficient cell line (HepG2). This formulation improved gene delivery showed by conventional lipoplexes or polyplexes resulting an efficient, simple, and nontoxic method for gene delivery of therapeutic genes in vitro and very probably in vivo.     

Folic acid conjugated mPEG-PEI600 as an efficient non-viral vector for targeted nucleic acid delivery

In this study we describe a novel polymer, mPPS-FA, synthesized as a potential gene transfer vector. To complete mPPS-FA, folic acid was conjugated to a backbone (named mPPS) consisting of a copolymer of methyl PEG-2000, PEI-600, and sebacoyl chloride. (1)H NMR, FT-IR, and UV spectroscopy were used to characterize the structure of mPPS-FA. It was revealed that mPPS-FA holds the ability to bind plasmid DNA yielding positively charged particles (polyplexes). Dynamic light scattering (DLS) and TEM techniques were used to study the size and morphology of the formed mPPS-FA/DNA nanocomplexes. The mPPS-FA/DNA nanoparticles exhibited low cytotoxicity as transfection of B16-F0, U87MG, CHO-1, and Ho-8910 cells produced >80% viability indicating low cytotoxicity of the polymer. The ability of mPPS-FA to deliver EGFP plasmid to melanoma B16-F0, U87, CHO-1, Ho-8910, and A549 cells was investigated in vitro as compared to the lipid-based transfection agent Lipofectamine2000 and Linear PEI 22 kDa (L-PEI 22 kDa). We found that mPPS-FA/DNA complexes yielded the highest GFP transfection efficiency in B16-F0, U87, CHO-1, and Ho-8910 cells, which all highly express folate receptors (FR), at an mPPS-FA/DNA ratio (w/w) of 15. Furthermore, the transfection of mPPS-FA/DNA complexes in CHO-1 cells could be competitively blocked by free folic acid molecules. In contrast, in low FR expressing A549 cells, mPPS-FA showed similar low transfection efficiency as mPPS. Taken together, mPPS-FA showed the highest efficiency in vitro and the potential to be developed as a nonviral gene carrier.     

Biodegradable nanoparticles composed of dendrigraft poly-l-lysine for gene delivery

We developed novel gene vectors composed of dendrigraft poly-l-lysine (DGL). The transgene expression efficiency of the pDNA/DGL complexes (DGL complexes) was markedly higher than that of the control pDNA/poly-l-lysine complex. However, the DGL complexes caused cytotoxicity and erythrocyte agglutination at high doses. Therefore, γ-polyglutamic acid (γ-PGA), which is a biodegradable anionic polymer, was added to the DGL complexes to decrease their toxicity. The resultant ternary complexes (DGL/γ-PGA complexes) were shown to be stable nanoparticles, and those with γ-PGA to pDNA charge ratios of >8 had anionic surface charges. The transgene expression efficiency of the DGL/γ-PGA complexes was similar to that of the DGL complexes; however, they exhibited lower cytotoxicity and did not induce erythrocyte agglutination at high doses. After being intravenously administered to mice, the DGL6 complex demonstrated high transfection efficiency in the liver, lungs, and spleen, whereas the DGL6/γ-PGA8 complex only displayed high transfection efficiency in the spleen. Future studies should examine the utility of DGL and DGL/γ-PGA complexes for clinical gene therapy.     

Targeted gene delivery to glioblastoma using a C-end rule RGERPPR peptide-functionalised polyethylenimine complex

Safe and efficient systems capable of specifically targeting brain tumour cells represent a promising approach for the treatment glioblastoma multiforme. Neuropilin-1 (NRP-1) is over-expressed in U87 glioma cells. In the current study, the tumour specific peptide RGERPPR, which binds specifically to NRP-1, was used as a targeting ligand in a gene delivery strategy for glioblastoma. The RGERPPR peptide was coupled to branched polyethylenimine (PEI, 25 kDa) using heterobifunctional Mal–PEG–NHS, resulting in a novel gene delivery polymer. Polymer/plasmid DNA (pDNA) complexes were formed and their sizes and zeta potentials were measured. Compared with the unmodified mPEG–PEI/pDNA complexes, the RGERPPR–PEG–PEI/pDNA complex led to a significant enhancement in intracellular gene uptake and tumour spheroid penetration. Furthermore, the RGERPPR–PEG–PEI/pDNA complex facilitated enhanced transfection efficiency levels, as well as a reduction in cytotoxicity when tested in U87 glioma cells in vitro. Most significantly of all, when complexes formed with pDsRED-N1 were injected into the tail vein of intracranial U87 tumour-bearing nude mice, the RGERPPR–PEG–PEI complexes led to improved levels of red fluorescence protein expression in the brain tissue. Taken together, the results show that RGERPPR–PEG–PEI could be used as a safe and efficient gene delivery vehicle with potential applications in glioblastoma gene delivery.     

Biocompatible complex coated with glycosaminoglycan for gene delivery

The purpose of this study was to develop a ternary complex of plasmid DNA (pDNA) electrostatically assembled with dendrigraft poly-l-lysine (DGL) and biodegradable glycosaminoglycan for effective and secure gene delivery. High gene expression of pDNA/DGL complex was confirmed with slight cytotoxicity and erythrocyte agglutination. Anionic ternary complexes of 55.4–223.8?nm were formed by the addition of a glycosaminoglycan such as chondroitin sulfate A (CS-A), chondroitin sulfate B (CS-B), chondroitin sulfate C (CS-C) or hyaluronic acid (HA). Using the cell line B16-F10, most of the ternary complexes showed only weak gene expression and little cytotoxicity, although the pDNA/DGL/CS-A complexes maintained a certain level of gene expression. In particular, the pDNA/DGL/CS-A8 complexes showed significantly higher gene expression than pDNA/DGL complexes in the presence of fetal bovine serum. Gene expression from the pDNA/DGL/CS-A8 complex was inhibited by a high concentration of CS-A and endocytosis inhibitors. After intravenous administration of the pDNA/DGL/CS-A8 complex and the pDNA/DGL complex into ddY mice, high gene expression was observed in the reticuloendothelial systems, the pDNA/DGL/CS-A complex is expected to be useful for gene therapy.     

A Potential Targeting Gene Vector Based on Biotinylated Polyethyleneimine/Avidin Bioconjugates

Purpose  To improve the gene delivery efficiency and safety of non-viral vector in liver cells, avidin, which exhibited good biocompatibility and remarkable accumulation in liver, was bioconjugated with biotinylated polyethylenimine to obtain a novel gene vector. Materials and methods  Biotinylated polyethyleneimine/avidin bioconjugate (ABP) was synthesized through grafting biotin to high molecular weight branched polyethylenimine (PEI, 25 kDa) and then bioconjugating with avidin by the biotin-avidin interaction. Physiochemical characteristics of ABP/pDNA complexes were analyzed, and in vitro cytotoxicity and transfection of ABP were also evaluated in HepG2, Hela and 293 T cells by using 25 kDa PEI as the control. Results  It was found that ABP was able to condense pDNA efficiently at N/P ratio of 4. The particle sizes of ABP/pDNA complexes were less than 220 nm, and the average surface charges were around 27 mV at the N/P ratio ranging from 2 to 60. Among three different cell lines, ABP and its DNA complexes demonstrated much lower cytotoxicity and higher transfection efficacy in HepG2 cells as compared with 25 kDa PEI. Conclusion  ABP presented higher transfection efficacy and safety in HepG2 cells due to the biocompatibility of avidin and the specific interactions between avidin and HepG2 cells.     

Comparative study of poly (lactic-co-glycolic acid)-poly ethyleneimine-plasmid DNA microparticles prepared using double emulsion methods

Controlled release of plasmid DNA (pDNA) from biodegradable poly lactic-co-glycolic acid (PLGA) microparticles has the potential to enhance transgene expression. However, barriers to this approach include limited encapsulation efficiency, pDNA damage during fabrication and confinement of the microparticles inside phagolysosomal compartments. Combining PLGA with poly ethyleneimine (PEI) can improve protection of pDNA during fabrication, increase encapsulation efficiencies and impart the PLGA microparticles with the capacity to escape the phagolysosomal compartments. This study compares three promising formulation methods for preparing PLGA PEI pDNA microparticles and evaluates for buffering capacity, cellular uptake, transfection efficiency and toxicity. In the first method, PLGA PEI pDNA microparticles are prepared by entrapping pDNA in blended PLGA/PEI using the double emulsion water-in-oil-in-water solvent evaporation technique (PA). In a second approach, PEI-pDNA polyplexes are prepared and then entrapped in PLGA microparticles using a double emulsion solvent evaporation method (PB). Microparticles prepared using formulation methods PA and PB are then compared against PLGA microparticles with PEI conjugated to the surface using carbodiimide chemistry (PC); 0.5% PVA is identified as the optimum concentration of surfactant for generating the strongest transfection efficiencies. N:P ratios of 5 and 10 are selected for preparation of each group. Gel electrophoresis demonstrates that all PLGA microparticle formulations have strong pDNA binding capacity. An MTT assay shows that in vitro cytotoxicity of PLGA PEI microparticles is significantly lower than PEI alone. PLGA PEI pDNA microparticles mediate higher cellular uptake efficiency and consequently higher transgene expression than unmodified PLGA microparticles in COS7 and HEK293 cells. Preparing PEI-pDNA polyplexes prior to entrapment in PLGA microparticles (PB) results in the highest pDNA loading. This is 2.5-fold higher than pDNA loading in unmodified PLGA microparticles. PLGA PEI pDNA microparticles prepared using method PB generates the strongest transfection efficiencies, which are 500-fold higher than unmodified PLGA pDNA microparticles in HEK293 cells and 1800-fold higher in COS-7 cells. The highest transfection efficiencies generated from microparticles prepared using method PB is achieved using an N:P ratio of 5.     

Enhancement of gene transfection into human dendritic cells using cationic PLGA nanospheres with a synthesized nuclear localization signal

Effective delivery of DNA encoding antigen into the dendritic cells (DCs), which are non-dividing cells, is very important for the development of DNA vaccines. In a previous study, we developed the PLGA nanospheres that contained a cationic nanomaterial and showed high transfection efficiency in COS7 cells, which divide. In the present study, to produce an effective vector for the DNA vaccines, the gene expression and intracellular trafficking of pDNA complexed with PLGA/PEI nanospheres, in combination with an NF-κB analog as a nuclear localization signal (NLS) and electroporation were evaluated in human monocyte-derived DCs (hMoDCs). Cellular uptake of pDNA both in COS7 cells and hMoDCs was enhanced using the PLGA/PEI nanospheres. On the other hand, the PLGA/PEI nanospheres significantly promoted the transfection in COS7 cells, but had almost no effect on transfection in hMoDCs. The intranuclear transport of pDNA by PLGA/PEI nanospheres in COS7 cells was significantly higher than that in hMoDCs. These results indicate that pDNA complexed with PLGA/PEI nanospheres cannot enter into the nuclei of non-dividing cells. However, PLGA/PEI nanospheres combinated with NLS and electroporation (experimental permeation enhancer) greatly elevated the transfection efficiency by improvement of not only intracellular uptake but also intranuclear transport of pDNA in the hMoDCs. Thus, this delivery system using nanospheres combined with synthesized NLS might be applicable to DC-based gene vaccines when much non-invasive application such as needle-free injector should be required.     

Influence of murine hepatitis induced by D-(+)-galactosamine hydrochloride and lipopolysaccharide on gene expression of polyethylenimine/plasmid DNA polyplex

We investigated the influence of murine hepatitis induced by D-(+)-galactosamine and lipopolysaccharide (D-GalN/LPS) on polyethylenimine (PEI)-mediated plasmid DNA (pDNA) delivery. pDNA encoding firefly luciferase was used as the model reporter gene. PEI was used as the non-viral vector because of its high gene expression and low toxicity. The activities of serum alanine aminotransferase (ALT) and aspartate aminotransferase (AST) in mice indicated the highest peaks at 12 h after D-GalN/LPS injection, then the activities of serum ALT and AST rapidly decreased. We determined luciferase activity in various organs of D-GalN/LPS-treated mice and control mice after an intravenous administration of PEI/pDNA complexes. High transgene expression was observed in the liver, spleen, and lung of both mice. Compared to the control mice, a significant increase of transgene expression was observed in the liver of D-GalN/LPS-treated mice after D-GalN/LPS injection. The transgene expression in the spleen and lung decreased at 6 and 12 h after D-GalN/LPS injection. In conclusion, we found that murine hepatitis induced by D-GalN/LPS injection can influence PEI-mediated pDNA delivery and its influence was different from that induced by CCl(4) injection which was reported previously. These results demonstrated the necessity of considering the timing and dose of gene therapy according to the disease and its stage.     

Poly(L-lactic acid)/polyethylenimine nanoparticles as plasmid DNA carriers

Non-viral vectors such as liposomes, polycations, and nanoparticles have been used as gene delivery systems. In this study, we prepared and characterized biodegradable poly(L-lactic acid) (PLA)/polyethylenimine (PEI) nanoparticles as gene carriers. pCMV/β-gal and pEGFP-C1 were utilized as model plasmid DNAs (pDNA). Nanoparticles were prepared using a double emulsion-solvent evaporation technique, and their pDNA binding capacity was assessed by agarose gel electrophoresis. Transfection was studied in HEK 293 and HeLa cell lines, and the transfection efficiencies were determined by β-galactosidase assay or flow cytometry. Three kinds of PLA/PEI systems were studied by varying the molecular weight of PEI. The PLA/PEI 25K system had a higher transfection efficiency than the PLA/PEI 0.8K or PLA/PEI 750K systems. The transfection efficiency was found to be dependent on the ratio of PLA/PEI nanoparticles to pDNA with an optimum ratio of 60:1 (w/w). The cytotoxicity was dependent on the quantity of PLA/PEI nanoparticles used, but it was comparable to that of commercial Lipofectin™. These results demonstrate the potential of PLA/PEI nanoparticles as gene carriers.     

Intracellular uptake and release of poly(ethyleneimine)-co-poly(methyl methacrylate) nanoparticle/pDNA complexes for gene delivery

Our previous studies demonstrated that cationic nanoparticles composed of well-defined poly(methyl methacrylate) (PMMA) cores surrounded by a hairly poly(ethyleneimine) (PEI) shells have comparative advantages over the PEI system for gene delivery. In this study, we focused on the intracellular uptake and release of PEI-PMMA nanoparticle/pDNA complexes. The behavior of the nanoparticle/pDNA complexes in recipient cells was monitored by using confocal laser scanning microscopy. We found that the nanoparticle/pDNA complexes were internalized very effectively by endocytosis. In the recipient cells the nanoparticles were found localized in the cytoplasm. At the same time, the pDNA carried by the nanoparticles successfully detached from the nanoparticles and localized in the nucleus of the HeLa cells.     

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.     

藻酸盐/PEI/DNA复合载体作为一种新型基因递送系统

目的克服多聚乙烯亚胺(PEI，polyethlenimine)/DNA载体对细胞的毒性以及在含血清培养基里对癌细胞基因的转移率低的问题。方法利用具有水溶性、可生物降解的、并带有负电的藻酸盐(alginate)对PEI/DNA载体进行包衣，制备出复合载体，并在体外含50%血清培养基里，与PEI/DNA载体比较对C3癌细胞转染率。结果 在含50%血清的培养基里，藻酸盐包衣制备的复合体载体［alginate:DNA，0.15 (w/w);PEI:DNA，N:P=10］与PEI/DNA载体相比，对C3癌细胞基因转染率高出10～30倍，而且其表面正电荷数比PEI/DNA载体减少了一半，颗粒较小，并降低对细胞毒性和红血球集聚反应。结论作为新型的藻酸盐包衣制备的复合载体能提高在体外含高浓度血清培养基里对C3癌细胞的转染率，并能减少其对细胞毒性。     

阴离子脂质体－阳离子脂质体复合物介导的基因转染

目的评价阴离子脂质体-阳离子脂质体复合物介导质粒转移至HepG2肝癌细胞中及其毒副作用。方法制备携载表达绿色荧光蛋白质粒的阳离子脂质体,与阴离子脂质体形成复合物。测定脂质体复合物的zeta电位,凝胶阻滞实验考察质粒包封情况,流式细胞仪测量各阴离子脂质体-阳离子脂质体复合物的转染效率,MTT法检测细胞毒性。结果复合物能完全包裹质粒,其zeta电位低于阳离子脂质体zeta电位;脂质体复合物介导的转染效率略低于阳离子脂质体,其细胞生存率高于阳离子脂质体。结论阴离子脂质体-阳离子脂质体复合物在降低细胞毒性的同时,可实现对HepG2细胞较高的转染效率。     

Design, synthesis and in vitro evaluation of a novel "stealth" polymeric gene vector

We report on the synthesis of a novel gene carrier that has low interaction with serum components, as well as low cytotoxicity. Cationic copolymers composing branched poly(ethylenimine) (PEI) grafted with hydrophilic poly(ethylene glycol) (PEG) and poly(l-lactic acid) (PLLA) or small-molecule oleoyl were synthesized and evaluated as novel gene carriers in this study. The copolymers were complexed with plasmid DNA and the resulting polyplexes were approximately 140 nm in diameter and had a positive surface potential (ζ = +13.8 mV) at the N/P ratio of 10/1. The experiments showed that copolymers with the oleoyl moiety were superior to the other two copolymers (with PLLA), in terms of in vitro gene transfection efficiency. Safety studies using MTT assay indicated much lower cytotoxicity of the oleoyl polyplexes than the pDNA/PEI complexes. The intracellular behavior of the polyplexes was monitored by confocal laser scanning microscopy, and it was found that the polyplexes were internalized into HeLa cells very effectively. At the same time, the plasmid DNA carried by the oleoyl-containing copolymers was found to localize in the nucleus of the recipient cells. One experiment comparing serum-free and serum-containing media indicated that the oleoyl polyplexes may be able to evade the reticulo-endothelial system (RES) better than the PEI–pDNA complex.     

PEG conjugation of a near-infrared fluorescent probe for noninvasive dual imaging of lung deposition and gene expression by pulmonary gene delivery

Dual imaging of lung deposition and gene expression following the pulmonary delivery of a gene formulation is useful for a precise analysis of gene transfection efficiency in vivo. As a novel probe for evaluating lung deposition, in this study, a poly(ethylene glycol)-conjugated near-infrared fluorescent probe (PEG-NIRF) was newly synthesized, and compared with indocyanine green (ICG), for application to pDNA/polyethyleneimine (PEI) complex. PEG-NIRF had superior characteristics including a larger Stokes shift (absorption maximum, 662?nm; emission maximum, 772?nm) and relatively equivalent fluorescence intensity compared with ICG. ICG affected the physicochemical properties of pDNA/PEI complex with a loss of fluorescence intensity, while PEG-NIRF did not. Experiments in mice demonstrated that PEG-NIRF showed greater lung localization than ICG following pulmonary co-delivery with pDNA/PEI complex, indicating the possibility of accurately evaluating lung deposition. Moreover, it was clarified that the evaluation of lung deposition by PEG-NIRF even at 60?min could be significantly correlated with gene expression in each mouse following pulmonary co-delivery with pDNA/PEI complex. These results suggest that PEG-NIRF is widely applicable to the dual imaging of the lung deposition and gene expression of inhaled gene formulations.     

Polyethylenimine Derivatives as Potent Nonviral Vectors for Gene Transfer

The delivery of a functional gene into a tissue can allow the correction of gene defaults or mutations such as those observed in severe hereditary pathologies or in cancer tissues and could lead to gene therapy. To achieve gene transfer, viral vectors are mainly used because of their intrinsic ability to enter the cells and promote expression of the transgene. However, many factors can limit the use of viral vectors, including a heavy laboratory infrastructure, and, in the case of iterative administration, the induction of immune response against viral proteins. Alternative gene transfer technologies based on nonviral vectors have been proposed. Polyethylenimine (PEI) derivatives are polycationic molecules that are able to form stable complexes with plasmidic DNA. PEI/DNA complexes attach to the cell surface, migrate into clumps that enter the cell by endocytosis and are deagregated in an acidic lysosomal compartment and/or enter the nucleus. PEI derivatives can be proposed as linear (22 kDa) or reticulated (25 kDa) molecules that prove efficient for gene transfer in vitro and in vivo. Besides extensive applications of unsubstituted PEI, glycosylated-PEI derivatives were proposed and reported to enhance gene transfer efficiency through decreased size and aggregation of PEI/DNA complexes. Galactosylated-PEI derivatives have been reported to enhance interactions with cell membranes through carbohydrate-binding protein recognition and specifically target PEI/DNA complexes toward biological systems that express galectins. More recently, glucosylated PEI derivatives have been shown to yield higher and longer-lasting transgene expression than unsubstituted-PEI in human head and neck carcinoma tumor cells. In the present paper, a review of in vitro and in vivo properties of PEI-mediated gene transfer experiments is presented. (c) 2002 Prous Science. All rights reserved.