Quantitative three-dimensional analysis of the intracellular trafficking of plasmid DNA transfected by a nonviral gene delivery system using confocal laser scanning microscopy.

Since endosomal escape and the nuclear delivery of plasmid DNA (pDNA) constitute major barriers for transgene expression, a quantitative evaluation of intracellular trafficking of pDNA would be highly desirable in terms of optimizing a nonviral gene delivery system. In the present study, a novel strategy is proposed for the quantification of rhodamine-labeled pDNA in endosomes/lysosomes, cytosol, and nucleus. Endosomes/lysosomes and nucleus were stained with LysoSensor DND-189 and Hoechst 33258, respectively, to distinguish them from the cytosol. The pixel areas of the clusters derived from the rhodamine were used as an index for the amount of pDNA. This approach was applied to the analysis of the intracellular trafficking of pDNA transfected by LipofectAMINE PLUS, stearylated octaarginine (STR-R8), and octaarginine (R8). In the case of R8, most of the pDNA was trapped by endosomes/lysosomes. STR-R8 exhibited endosomal escape followed by nuclear translocation in a time-dependent manner. LipofectAMINE PLUS was the most effective in rapidly delivering pDNA to the nucleus as well as the cytosol. These differences in the intracellular trafficking of pDNA correlated well with the transgene expression. Therefore, this method enables the quantitative analysis of the intracellular pharmacokinetics of pDNA and promises to provide useful information for optimizing nonviral gene delivery systems.     

Immunostimulatory characteristics induced by linear polyethyleneimine-plasmid DNA complexes in cultured macrophages

Intravenously injected plasmid DNA (pDNA) complexed with cationic liposome (lipoplexes) caused NF-kappaB-mediated cytokine production from macrophages, induced by CpG sequence in the pDNA. We have reported that cytokine production caused by linear polyethyleneimine (PEI)-pDNA complexes (PEI polyplexes) was much lower than that caused by lipoplexes (Kawakami, S., Ito, Y., Charoensit, P., Yamashita, F., and Hashida, M. [2006]. J. Pharmacol. Exp. Ther. 317, 1382-1390). As Toll-like receptor-9 recognizing CpG sequence is expressed in the endosomal compartment, we hypothesized that the buffering capacity of PEI enhanced the escape of PEI polyplexes from endosomes, and that consequently cytokine production was decreased. In this study, the mechanism of lower cytokine production induced by PEI polyplexes, compared with lipoplexes, was investigated using the murine macrophage-like cell line RAW 264.7. Although transfection efficacy and cellular association were similar for PEI polyplexes and lipoplexes, tumor necrosis factor-alpha and interleukin-6 production and NF-kappaB activation caused by polyplexes were significantly lower than with lipoplexes. As for intracellular distribution, PEI polyplexes spread into cytosol whereas lipoplexes accumulated in vesicles, suggesting enhancement of escape from endosomes by PEI. Bafilomycin A1, an inhibitor of early endosomes, enhanced cytokine production and NF-kappaB activation by PEI polyplexes but not by lipoplexes; however, chloroquine, an inhibitor of late endosomes, inhibited PEI polyplex-induced cytokine production and NF-kappaB activation, suggesting that the buffering effect of PEI on early endosomes decreases NF-kappaB-mediated cytokine production. In conclusion, we demonstrate that cytokine production and NF-kappaB activation induced by PEI polyplexes are significantly lower than with lipoplexes in cultured macrophages. The significantly low cytokine response of PEI polyplexes may be due to effective transition of PEI polyplexes from endosomes to cytosol.     

Enhanced internalization and endosomal escape of dual-functionalized poly(ethyleneimine)s polyplex with diphtheria toxin T and R domains

A new multifunctional gene delivery system was constructed with diphtheria toxin's functional domains. Used functional domains are T domain for endosomal escape and R domain for efficient internalization into cell. In order to conjugate these domains into PEI polyplex, diphtheria toxin T and R domains-streptavidin fusion protein (DTRS) was prepared. The conjugation of the DTRS with biotinylated PEI polyplex (DTRS-polyplex) lead to the significant enhancement of transfection efficiency when compared with plain PEI/pDNA polyplex in CHO-K1 cell. It was demonstrated that DTRS-polyplex had high endosomal escape efficiency and internalization efficiency by several measurements, such as in vitro intracellular trafficking observation and the internalization inhibition with several inhibitors. These results suggest that this multifunctional non-viral vector may contribute to the future cancer gene therapy.     

转化生长因子β1基因缓释的壳聚糖纳米粒制备及体外检测

背景：壳聚糖作为一种非病毒载体,具有低毒性、低免疫原性、良好的生物相容性以及带可高正电荷密度的特性,易与带负电荷的DNA通过静电作用形成相互作用体避免核酸酶的降解。目的：构建负载重组人转化生长因子β1基因的壳聚糖纳米粒,检测其体外缓释转化生长因子β1基因及对软骨细胞基因转染等性能。方法：将壳聚糖与负载增强型绿色荧光蛋白基因和转化生长因子β1基因的质粒DNA（pDNA）以复凝聚法制成壳聚糖/pEGFP-TGF-β1纳米粒。结果与结论：制备的壳聚糖/pEGFP-TGF-β1纳米粒呈球形,粒径、表面电位与pH值相关,随着pH值升高,粒径增大,表面电位减少。纳米粒可有效保护pDNA免受核酸酶的降解。纳米粒的pDNA包封率为（87.5±2.3）%;pDNA可从纳米粒中缓慢释放。体外转染实验证实壳聚糖/pEGFP-TGF-β1纳米粒能转染软骨细胞并在细胞内表达绿色荧光蛋白。提示壳聚糖/pEGFP-TGF-β1纳米粒能有效保护pDNA免受核酸酶降解,具有良好的缓释转化生长因子β1基因的能力,并能介导基因转染软骨细胞。     

Macropinocytosis of polyplexes and recycling of plasmid via the clathrin-dependent pathway impair the transfection efficiency of human hepatocarcinoma cells.

Knowledge of the entry mechanism and intracellular routing of polyplexes is of major importance for designing efficient gene delivery systems. We therefore investigated the internalization and trafficking of polyplexes in HepG2 cells. pDNA encoding the luciferase was complexed with histidylated polylysine (His-pLK), a polymer that requires acidic pH for pDNA endosomal release. Fluoresceinylated polyplexes (F-His-pLK or F-pDNA) were internalized by clathrin-dependent and -independent pathways. The latter most likely occurred by macropinocytosis since it was stimulated by phorbol myristate and blocked by dimethylamiloride. Intracellular routing of the plasmid was analyzed by confocal microscopy and flow cytometry. These data revealed that: (i) one part of the plasmid was present in vesicles that were not labeled with any known organelle-specific marker, (ii) the other part was in transferrin receptor-positive vesicles, and (iii) the plasmid was not transferred to late endosomes/lysosomes. Using luciferase activity as a readout for gene expression, we found that it was strongly reduced when macropinocytosis was stimulated, whereas macropinocytosis inhibitors had no effect. However, blocking clathrin-dependent internalization by chlorpromazine completely prevented gene expression. These findings demonstrate that: (i) macropinocytosis of polyplexes and (ii) plasmid recycling impair the transfection efficiency and (iii) clathrin-dependent endocytosis is the most productive route for transfection of HepG2 cells.     

Bioreducible polymers with cell penetrating and endosome buffering functionality for gene delivery systems

Bioreducible cationic polymers (p(DAH_a-R/API_b)s) composed of different ratios (a:b = 2:1, 1:1, 1:2) between arginine-grafted diaminohexane (DAH-R) (cell penetrating functionality) and 1-(3-aminopropyl) imidazole (API) (endosome buffering functionality) monomers were synthesized by Michael reaction of N,N′-cystaminebisacrylamide (CBA) with them, in order to study the effect of endosome buffering moiety on arginine-grafted bioreducible polymeric gene carriers. Several experiments displayed a distinct correlation between monomer composition ratios of p(DAH-R/API)s and the polymer features. Increased endosome buffering capacities proportional to API portions was evaluated for p(DAH-R/API)s due to the imidazole group (pKa = 6) of API. Increased portions of API non-ionized at physiological pH and resultant decrease of arginine residues also reduced cytotoxicities of the polymers due to less interaction of cellular compartments with less positively charged polymers but decreased pDNA condensing abilities, Zeta-potential values, cellular uptakes of polyplexes, and finally transfection efficiencies as well. Thus, the predominance of arginine residues over endosome buffering moieties was revealed regarding efficient gene delivery for p(DAH-R/API)s. From transfection results with chloroquine or nigericin, it can be deduced that the endosomal escape of p(DAH-R/API) polyplexes occurs by direct endosome membrane penetration of arginine moieties as well as endosome buffering of the polymers after cellular uptake, which emphasizes the importance of arginine moieties for polymeric gene delivery systems.     

Imidazole groups on a linear, cyclodextrin-containing polycation produce enhanced gene delivery via multiple processes.

The linear, cyclodextrin-containing polycation (CDP) is one of many non-viral gene delivery vectors that show improved transfection efficiency when modified to have pH-buffering capacity. The buffering activity is presumed to confer enhanced ability to escape the endocytic pathway. Here, the differences in delivery behavior between CDP and its pH-buffering, imidazole-containing variant (CDPim) are investigated in order to elucidate the mechanism(s) by which these related materials exhibit differences in gene delivery. In cell-free assays that include dye exclusion and heparan sulfate displacement, CDP appears to have weaker binding strength with nucleic acids than CDPim. Numerous analyses involving transfected cells, however, indicate that CDPim more readily releases nucleic acids in the intracellular setting. Together, these data suggest that differences in transfection efficiency between CDP and CDPim result from factors beyond buffering activity and endosomal escape.     

Improved packing of poly(ethylenimine)/DNA complexes increases transfection efficiency.

We have developed a modified poly(ethylenimine) (PEI) transfection procedure that significantly increases PEI's transfection efficiency. While the basic transfection procedure had a transfection efficiency of 37%, our modified procedure yielded a 53% transfection efficiency. The altered procedure gives improved results because of two simultaneous actions: free polycations are removed from the transfecting solutions, and the composition of the PEI complexes that are administered to cells has been modified. The reduction in the amount of free polycations in transfecting solutions reduced the toxicity sometimes associated with the administration of polycations to cellular environments. The structural modification of PEI/DNA transfecting complexes involves improved PEI packing around the delivered plasmid to yield a greater buffering capacity without a change in the complex's surface charge concentration. These structural properties were confirmed by titration and zeta potential analyses. Whether the modified PEI/DNA complexes are more effective because of increased cellular uptake or an enhanced ability to escape from endolysosomes has been addressed. The increase in transfection efficiency was obtained when the buffering capacity of the PEI/DNA was increased without a change in surface charge concentration, which implies that it is the property of enhanced lysosomal buffering that is responsible for successful PEI transfection.     

Enhanced folate receptor mediated gene therapy using a novel pH-sensitive lipid formulation.

Liposomal gene therapy vectors that penetrate cells by endocytosis must escape an endosomal compartment in order to enter the target cell's nucleus. Because such endosomal compartments are generally acidic in nature, pH-sensitive liposomes have been designed that are stable at extracellular pH ( approximately pH 7.4) but fusogenic at endosomal pH values ( approximately pH 5). We report here the use of a novel folate-targeted, pH-sensitive, anionic liposomal vector that mediates the efficient delivery of DNA into folate receptor-bearing cells and discharges the DNA into the cytoplasm. N-Citraconyl-dioleoylphosphatidylethanolamine (C-DOPE), a derivative of dioleylphosphatidylethanolamine (DOPE) that hydrolyzes rapidly at pH 5 to yield DOPE, was synthesized and incorporated with DOPE and folate-polyethyleneglycol-DOPE into liposomes. The resulting liposomes were stable at neutral pH but fusogenic at pH 5. Folate-labeled gene transfer vectors were prepared by compacting plasmid DNA with polylysine at a 1:0.75 (w/w) ratio and complexing the condensed cationic plasmid with the above anionic liposomes. Association of the polylysine-DNA with the liposomes was confirmed by sucrose gradient centrifugation, where migration of the folate-labeled vectors was midway between that of the free liposomes and condensed polylysine-DNA. Transfection of cultured cancer cells with the pH-sensitive liposomal vectors was found to be significantly more efficient than transfection with DOPE-cholesterol hemisuccinate-based vectors, the more commonly used pH-dependent, liposomal transfection formulation. Optimization studies revealed that inclusion of only 3% C-DOPE and 0.1% folate-derivatized DOPE yielded the highest transfection activity. Nearly quantitative competition with free folic acid as well as direct correlation of transfection efficiency with folate receptor density for several different cell lines further documented that vector uptake was mediated by folate receptor endocytosis. Taken together, these data argue that C-DOPE warrants further consideration as a pH sensitive component of lipid-based gene delivery formulations.     

Nanoparticle mediated delivery of pure P53 supercoiled plasmid DNA for gene therapy

The translation of non-viral gene replacement therapies for cancer into clinical application is currently hindered due to known issues associated with the effectiveness of plasmid DNA (pDNA) expression vectors and the production of gene delivery vehicles. Herein we report an integrative approach established on the synthesis of nanoparticulated carriers, in association with the supercoiled (sc) isoform purification of a p53 tumor suppressor encoding plasmid, to improve both delivery and transfection. An arginine-based chromatographic matrix with specific recognition for the different topoisoforms was used to completely isolate the biologically active sc pDNA. Our findings showed that the sc topoisoform is recovered under mild conditions with high purity and structural stability. In addition, to further enhance protection and transfection efficiency, the naked sc pDNA was encapsulated within chitosan nanoparticles by ionotropic gelation. The mild conditions for particle synthesis used in the former technique allowed the attainment of a high encapsulation efficiency for sc pDNA (> 75%). Moreover, in vitro transfection experiments confirmed the reinstatement of the p53 protein expression and most importantly, the sc pDNA transfected cells exhibited the highest p53 expression levels when compared to other formulations. Overall, given the fact that sc pDNA topoisoform indeed enhances transgene expression rates this approach might have a profound impact on the development of a sustained nucleic acid-based therapy for cancer.     

PEGylated gene nanocarriers based on block catiomers bearing ethylenediamine repeating units directed to remarkable enhancement of photochemical transfection.

The therapeutic usefulness of macromolecular drugs such as plasmid DNA is often limited by the inefficient transfer of macromolecules to the cytosol. Photochemical internalization (PCI) technology, in which the endosomal escape of DNA or its complex is assisted by co-incubated photosensitizers that photodamage endosome membrane, offers a solution for this problem. A series of poly(ethylene glycol) (PEG)-based block polycatiomers with increasing number of ethylenediamine repeating unit at side chain of polycatiomers were complexed with pDNA to form the PEGylated polyplexes as a biocompatible gene carrier. Dendrimeric phthalocyanine (DPc)-incorporated micelle was used to assist the gene transfer of these polyplexes in a light-inducible manner. As a result, the light-inducible transfection activity was significantly enhanced as the number of amino group at the side chain of PEG-b-polycatiomer increased. The polyplex from PEG-b-polycatiomer having the longest ethylenediamine structure achieved approximately 1000-fold enhancement of transfection upon photoirradiation. This result supports the underlying hypothesis that photochemical transfection and proton sponge effect of polycations can work synergistically to enhance the transfection efficiency. With careful balance between photochemical transfection enhancement and cytotoxicity, PEG-b-polycatiomers used in this study might be a potential candidate for in vivo PCI-mediated gene transfer.     

Intracellular Trafficking and Decondensation Kinetics of Chitosan�CpDNA Polyplexes

The transfection efficiency (TE) of chitosan–plasmid DNA (pDNA) polyplexes can be critically modulated by the polymer degree of deacetylation (DDA) and molecular weight (MW). This study was performed to test the hypothesis that the TE dependence on chitosan MW and DDA is related to the polyplex stability, hence their intracellular decondensation/unpacking kinetics. Major barriers to nonviral gene transfer were studied by image-based quantification. Although uptake increased with increased DDA, it did not appear to be a structure-dependent process affecting TE, nor was nuclear entry. Colocalization analysis showed that all chitosans trafficked through lysosomes with similar kinetics. Fluorescent resonant energy transfer (FRET) analysis revealed a distinct relationship between TE and polyplex dissociation rate. The most efficient chitosans showed an intermediate stability and a kinetics of dissociation, which occurred in synchrony with lysosomal escape. In contrast, a rapid dissociation before lysosomal escape was found for the inefficient low DDA chitosan whereas the highly stable and inefficient complex formed by a high MW and high DDA chitosan did not dissociate even after 24 hours. This study identified that the kinetics of decondensation in relation to lysosomal escape was a most critical structure-dependent process affecting the TE of chitosan polyplexes.     

Particle Tracking of Intracellular Trafficking of Octaarginine-modified Liposomes: A Comparative Study With Adenovirus

It is previously reported that octaarginine (R8)-modified liposome (R8-Lip) was taken up via macropinocytosis, and subsequently delivered to the nuclear periphery. In the present study, we investigated the mechanism for the cytoplasmic transport of R8-Lips, comparing with that for adenovirus. Treatment with microtubule-disruption reagent (nocodazole) inhibited the transfection activity of plasmid DNA (pDNA)-encapsulating R8-Lip more extensively than that of adenovirus. The directional transport of R8-Lips along green fluorescent protein (GFP)–tagged microtubules was observed; however, the velocity was slower than those for adenovirus or endosomes that were devoid of R8-Lips. These directional motions were abrogated in R8-Lips by nocodazole treatment, whereas adenovirus continued to undergo random motion. This finding suggests that the nuclear access of R8-Lip predominantly involves microtubule-dependent transport, whereas an apparent diffusive motion is also operative in nuclear access of adenovirus. Furthermore, quantum dot-labeled pDNA underwent directional motion concomitantly with rhodamine-labeled lipid envelopes, indicating that the R8-Lips were subject to microtubule-dependent transport in the intact form. Dual particle tracking of carriers and endosomes revealed that R8-Lip was directionally transported, associated with endosomes, whereas this occurs after endosomal escape in adenovirus. Collectively, the findings reported herein indicate that vesicular transport is a key factor in the cytoplasmic transport of R8-Lips.     

Use of ultrasound to enhance nonviral lung gene transfer in vivo

We have assessed if high-frequency ultrasound (US) can enhance nonviral gene transfer to the mouse lung. Cationic lipid GL67/pDNA, polyethylenimine (PEI)/pDNA and naked plasmid DNA (pDNA) were delivered via intranasal instillation, mixed with Optison microbubbles, and the animals were then exposed to 1 MHz US. Addition of Optison alone significantly reduced the transfection efficiency of all three gene transfer agents. US exposure did not increase GL67/pDNA or PEI/pDNA gene transfer compared to Optison-treated animals. However, it increased naked pDNA transfection efficiency by approximately 15-fold compared to Optison-treated animals, suggesting that despite ultrasound being attenuated by air in the lung, sufficient energy penetrates the tissue to increase gene transfer. US-induced lung haemorrhage, assessed histologically, increased with prolonged US exposure. The left lung was more affected than the right and this was mirrored by a lesser increase in naked pDNA gene transfer, in the left lung. The positive effect of US was dependent on Optison, as in its absence US did not increase naked pDNA transfection efficiency. We have thus established proof of principle that US can increase nonviral gene transfer, in the air-filled murine lung.     

Efficient gene delivery by urocanic acid-modified chitosan.

Nonviral delivery systems for gene therapy have been increasingly proposed as safer alternatives to viral vectors. Chitosan is considered to be a good candidate for the gene delivery system since it is already known as a biocompatible, biodegradable, and low toxic material with high cationic charge potential. However, the use of chitosan for gene delivery is limited due to low transfection efficiency. To enhance the transfection efficiency, water-soluble chitosan (WSC) was coupled with urocanic acid (UA) bearing imidazole ring which can play the crucial role in endosomal rupture through proton sponge mechanism. The urocanic acid-modified chitosan (UAC) was complexed with DNA, and UAC/DNA complexes were characterized. The sizes of UAC/DNA complexes under physiological condition (109-342 nm) were almost same as those of chitosan-DNA complexes. UAC also showed good DNA binding ability, high protection of DNA from nuclease attack, and low cytotoxicity. The transfection efficiency of chitosan into 293T cells was much enhanced after coupling with UA and increased with an increase of UA contents in the UAC.     

Chitosan as a nonviral gene delivery system. Structure-property relationships and characteristics compared with polyethylenimine in vitro and after lung administration in vivo

Chitosan is a natural cationic linear polymer that has recently emerged as an alternative nonviral gene delivery system. We have established the relationships between the structure and the properties of chitosan-pDNA polyplexes in vitro. Further, we have compared polyplexes of ultrapure chitosan (UPC) of preferred molecular structure with those of optimised polyethylenimine (PEI) polyplexes in vitro and after intratracheal administration to mice in vivo. Chitosans in which over two out of three monomer units carried a primary amino group formed stable colloidal polyplexes with pDNA. Optimized UPC and PEI polyplexes protected the pDNA from serum degradation to approximately the same degree, and they gave a comparable maximal transgene expression in 293 cells. In contrast to PEI, UPC was non toxic at escalating doses. After intratracheal administration, both polyplexes distributed to the mid-airways, where transgene expression was observed in virtually every epithelial cell, using a sensitive pLacZ reporter containing a translational enhancer element. However, the kinetics of gene expression differed - PEI polyplexes induced a more rapid onset of gene expression than UPC. This was attributed to a more rapid endosomal escape of the PEI polyplexes. Although this resulted in a more efficient gene expression with PEI polyplexes, UPC had an efficiency comparable to that of commonly used cationic lipids. In conclusion, this study provides insights into the use of chitosan as a gene delivery system. It emphasises that chitosan is a nontoxic alternative to other cationic polymers and it forms a platform for further studies of chitosan-based gene delivery systems.     

A novel glutathione modified chitosan conjugate for efficient gene delivery

A novel non-viral gene vector based on poly[poly(ethylene glycol) methacrylate] (PMPEG) and l-glutathione (GSH) grafted chitosan (CS) has been fabricated. First, well-defined brush-like PMPEG living polymers with dithioester residues were prepared by the reversible addition-fragmentation chain transfer (RAFT) polymerization and grafted onto the allylchitosan via radical coupling method. Then, the tripeptide GSH was introduced onto the end of PMPEG chain to give a CS-PMPEG-GSH conjugate. In comparison with pristine chitosan, CS-PMPEG-GSH conjugate could not only condense plasmid DNA (pDNA) and prevent the condensed CS-PMPEG-GSH/pDNA nanoparticle self-aggregation, but also increase the binding ability to cell membrane efficiently and improve decondensed ability of pDNA from the nanoparticles in cytoplasm which thus has resulted in the higher transfection efficiency in mouse embryonic fibroblast cells (NIH3T3). In addition, cytotoxicity assays showed that the conjugate is less cytotoxic than CS, and still retain the cationic polyelectrolyte characteristic as chitosan. These results indicate that the non-viral vector is a promising candidate for gene therapy in clinical application.     

Combination of chondroitin sulfate and polyplex micelles from Poly(ethylene glycol)-poly{N’-[N-(2-aminoethyl)-2-aminoethyl]aspartamide} block copolymer for prolonged in vivo gene transfection with reduced toxicity

Nonviral polycation-based gene carriers (polyplexes) have attracted attention as safe and efficient gene delivery systems. Polyplex micelles comprised of poly(ethyleneglycol)-block-poly{N’-[N-(2-aminoethyl)-2-aminoethyl]aspartamide} (PEG-PAsp(DET)) and plasmid DNA (pDNA) have shown high transfection efficiency with low toxicity due to the pH-sensitive protonation behavior of PAsp(DET), which enhances endosomal escape, and their self-catalytic degradability under physiological conditions, which reduces cumulative toxicity during transfection. In this study, we improved the safety and transfection efficiency of this polyplex micelle system by adding an anionic polycarbohydrate, chondroitin sulfate (CS). A quantitative assay for cell membrane integrity using image analysis software showed that the addition of CS markedly reduced membrane damage caused by free polycations in the micelle solution. It also reduced tissue damage and subsequent inflammatory responses in the skeletal muscle and lungs of mice following in vivo gene delivery with the polyplex micelles. Subsequently, this led to prolonged transgene expression in the target organs. This combination of polyplex micelles and CS holds great promise for safe and efficient gene introduction in clinical settings.     

Non-ionic amphiphilic biodegradable PEG-PLGA-PEG copolymer enhances gene delivery efficiency in rat skeletal muscle.

Naked plasmid DNA (pDNA)-based gene therapy has low delivery efficiency, and consequently, low therapeutic effect. We present a biodegradable nonionic triblock copolymer, PEG(13)-PLGA(10)-PEG(13), to enhance gene delivery efficiency in skeletal muscle. Effects of PEG(13)-PLGA(10)-PEG(13) on physicochemical properties of pDNA were evaluated by atomic force microscopy (AFM) imaging, gel electrophoresis and zeta-potential analysis. AFM imaging suggested a slightly compacted structure of pDNA when it was mixed with the polymer, while zeta-potential measurement indicated an increased surface potential of negatively charged pDNA. PEG(13)-PLGA(10)-PEG(13) showed a relatively lower toxicity compared to Pluronic P85 in a skeletal muscle cell line. The luciferase expression of pDNA delivered in 0.25% polymer solution was up to three orders of magnitude more than branched polyethylenimine (bPEI(25 k))/pDNA and three times more than that of naked pDNA five days after intramuscular administration. This in vivo gene delivery enhancement was also observed displaying a two-fold higher expression of human vascular endothelial growth factor (VEGF). Based on fluorescence labeled pDNA distribution, it is speculated that the greater diffusivity of PEG(13)-PLGA(10)-PEG(13)/pDNA compared to bPEI(25 k)/pDNA accounts for better transfection efficiency in vivo. To summarize, combining PEG(13)-PLGA(10)-PEG(13) with pDNA possesses the potential to improve gene delivery efficiency in skeletal muscle.     

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

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