Amphiphilic peptide carrier for the combined delivery of curcumin and plasmid DNA into the lungs

In this study, the R7L10 peptide, which is composed of a 7-arginine stretch and a 10-leucine stretch, was evaluated as a carrier for the combined delivery of curcumin and plasmid DNA (pDNA) into the lungs. Curcumin is a natural product with anti-inflammatory and anti-tumor effects. Curcumin-loaded R7L10 (R7L10-curucmin) was prepared by an oil-in-water (O/W) emulsion/solvent evaporation method. In vitro transfection showed that R7L10-curcumin had higher transfection efficiency than R7L10. Although R7L10-curcumin had lower transfection efficiency than polyethylenimine (25 kDa, PEI25k) and lipofectamine, R7L10-curcumin had lower cytotoxicity. In gel retardation assays and heparin competition assays, R7L10-curcumin formed a more stable complex with pDNA than R7L10. The intracellular curcumin delivery efficiency of R7L10-curcumin was higher than that of curcumin only. Furthermore, R7L10-curcumin more efficiently decreased TNF-α level in lipopolysaccharide (LPS)-activated Raw264.7 macrophage cells than curcumin only. For in vivo evaluation, pDNA/R7L10-curcumin complexes were administered into mouse lungs by intratracheal instillation. The results revealed that R7L10-curcumin delivered pDNA more efficiently than R7L10, poly-L-lysine (PLL), or PEI25k. In addition, R7L10-curcumin decreased TNF-α level in lung tissues in an acute lung injury mouse model. In contrast to PEI25k, R7L10-curcumin did not show liver toxicity after intravenous injection. These results suggest that R7L10-curcumin is a useful carrier for the combined delivery of curcumin and pDNA into the lungs.     

Ternary complexes of pDNA,polyethylenimine, and γ-polyglutamic acid for gene delivery systems

We discovered a vector coated by γ-polyglutamic acid (γ-PGA) for effective and safe gene delivery. In order to develop a useful non-viral vector, we prepared several ternary complexes constructed with pDNA, polyethylenimine (PEI), and various polyanions, such as polyadenylic acid, polyinosinic–polycytidylic acid, α-polyaspartic acid, α-polyglutamic acid, and γ-PGA. The pDNA/PEI complex had a strong cationic surface charge and showed extremely high transgene efficiency although it agglutinated with erythrocytes and had extremely high cytotoxicity. Those polyanions changed the positive ζ-potential of pDNA/PEI complex to negative although they did not affect the size. They had no agglutination activities and lower cytotoxicities but most of the ternary complexes did not show any uptake and gene expression; however, the pDNA/PEI/γ-PGA complex showed high uptake and gene expression. Most of the pDNA/PEI/γ-PGA complexes were located in the cytoplasm without dissociation and a few complexes were observed in the nuclei. Hypothermia and the addition of γ-PGA significantly inhibited the uptake of pDNA/PEI/γ-PGA by the cells, although l-glutamic acid had no effect. These results strongly indicate that the pDNA/PEI/γ-PGA complex was taken up by γ-PGA-specific receptor-mediated energy-dependent process. Thus, the pDNA/PEI/γ-PGA complex is useful as a gene delivery system with high transfection efficiency and low toxicity.     

Characterization of lactoferrin as a targeting ligand for nonviral gene delivery to airway epithelial cells

In this study lactoferrin (Lf) was investigated as a targeting ligand for receptor-mediated gene delivery to human bronchial epithelial cells. A high number of lactoferrin receptors (LfRs) were detected on bronchial epithelial (BEAS-2B), but not on alveolar epithelial (A549) cells by fluorescence microscopy and FACS measurements, suggesting potential targeting selectivity for bronchial epithelial cells. Molecular conjugates with ratios of Lf to branched polyethylenimine 25 kDa (PEI) ranging from 4:1 to 1:40 (mol/mol) were synthesized and analyzed for complexation of plasmid DNA (pDNA), transfection efficiency, and cytotoxicity. Whereas particle size increased with the degree of Lf coupling from 45 to 225 nm, surface charge was not significantly influenced. Transfection studies on BEAS-2B cells revealed that Lf-PEI 1:20 exhibited the highest luciferase gene expression which was 5-fold higher at an N/P ratio (molar ratio of PEI nitrogen to pDNA phosphate) of 4 than PEI and could be inhibited by an excess of free Lf. With A549 cells, no significant enhancement in transfection efficiency between Lf-PEI/pDNA and PEI/pDNA complexes could be observed. Increasing the degree of Lf coupling to PEI resulted in reduced transfection efficiency in both alveolar and bronchial epithelial cells. Cell viability assays resulted in significantly lower cellular toxicity of Lf-PEI/pDNA compared with PEI/pDNA complexes. We suggest that Lf represents a potent targeting ligand for receptor-mediated gene delivery to bronchial epithelial cells and might be a promising candidate for lung gene transfer in vivo.     

Gene transfection of hyperbranched PEI grafted by hydrophobic amino acid segment PBLG

The complex copolymer of hyperbranched polyethylenimine (PEI) with hydrophobic poly(gamma-benzyl L-glutamate) segment (PBLG) at their chain ends was synthesized. This water-soluble copolymer PEI-PBLG (PP) was characterized for DNA complexation (gel retardation assay, particle size, DNA release and DNase I protection), cell viability and in vitro transfection efficiency. The experiments showed that PP can effectively condense pDNA into particles. Size measurement of the complexes particles indicated that PP/DNA tended to form smaller nanoparticles than those of PEI/DNA, which was caused by the hydrophobic PBLG segments compressing the PP/DNA complex particles in aqueous solution. The representative average size of PP/DNA complex prepared using plasmid DNA (pEGFP-N1, pDNA) was about 96 nm. The condensed pDNA in the PP/pDNA complexes was significantly protected from enzymatic degradation by DNase I. Cytotoxicity studies by MTT colorimetric assays suggested that the PP had much lower toxicity than PEI. The in vitro transfection efficiency of PP/pDNA complexes improved a lot in HeLa cells, Vero cells and 293T cells as compared to that of PEI-25K by the expression of Green Fluorescent Protein (GFP) as determined by flow cytometry. Thus, the water-soluble PP copolymer showed considerable potential as carriers for gene delivery.     

A biodegradable poly(ester amine) based on polycaprolactone and polyethylenimine as a gene carrier

The aim of research was to develop and optimize delivery systems for plasmid DNA (pDNA) based on biodegradable polymers, in particular, poly(ester amine)s (PEAs), suitable for non-viral gene therapy. Poly(ester amine)s were successfully synthesized by Michael addition reaction between polycaprolactone (PCL) diacrylate and low molecular weight polyethylenimine (PEI). PEA/DNA complexes showed effective and stable DNA condensation with the particle sizes below 200nm, implicating its potential for intracellular delivery. PEAs showed controlled degradation and were essentially non-toxic in all three cells (293T: Human kidney carcinoma, HepG2: Human hepatoblastoma and HeLa: Human cervix epithelial carcinoma cell lines) at higher doses in contrast to PEI 25K. PEAs also revealed much higher transfection efficiencies in three cell lines as compared to PEI 25K. The highest reporter gene expression was observed for PCL/PEI-1.2 (MW 1200) complex having transfection efficiency 15-25 folds higher than PEI 25K in vitro. Also PEA/DNA complexes successfully transfected cells in vivo after aerosol administration than PEI 25K. These PEAs can be used as most efficient polymeric vectors which provide a versatile platform for further investigation of structure property relationship along with the controlled degradation, significant low cytotoxicity and high transfection efficiency.     

Cationic star polymers consisting of alpha-cyclodextrin core and oligoethylenimine arms as nonviral gene delivery vectors

A series of novel cationic star polymers were synthesized by conjugating multiple oligoethylenimine (OEI) arms onto an alpha-cyclodextrin (alpha-CD) core as nonviral gene delivery vectors. The molecular structures of the alpha-CD-OEI star polymers, which contained linear or branched OEI arms with different chain lengths ranging from 1 to 14 ethylenimine units, were characterized by using size exclusion chromatography, 13C and 1H NMR, and elemental analysis. The alpha-CD-OEI star polymers were studied in terms of their DNA binding capability, formation of nanoparticles with plasmid DNA (pDNA), cytotoxicity, and gene transfection in cultured cells. All the alpha-CD-OEI star polymers could inhibit the migration of pDNA on agarose gel through formation of complexes with pDNA, and the complexes formed nanoparticles with sizes ranging from 100 to 200 nm at N/P ratios of 8 or higher. The star polymers displayed much lower in vitro cytotoxicity than that of branched polyethylenimine (PEI) of molecular weight 25K. The alpha-CD-OEI star polymers showed excellent gene transfection efficiency in HEK293 and Cos7 cells. Generally, the transfection efficiency increased with an increase in the OEI arm length. The star polymers with longer and branched OEI arms showed higher transfection efficiency. The best one of the star polymers for gene delivery showed excellent in vitro transfection efficiency that was comparable to or even higher than that of branched PEI (25K). The novel alpha-CD-OEI star polymers with OEI arms of different chain lengths and chain architectures can be promising new nonviral gene delivery vectors with low cytotoxicity and high gene transfection efficiency for future gene therapy applications.     

Nanosphere-mediated delivery of vascular endothelial growth factor gene for therapeutic angiogenesis in mouse ischemic limbs

Polymeric nanosphere-mediated gene delivery may sustain the duration of plasmid DNA (pDNA) administration. In this study, poly(lactic-co-glycolic acid) (PLGA) nanospheres were evaluated as a gene carrier. The pDNA-loaded PLGA nanospheres were formulated with high encapsulation efficiency (87%). The nanospheres sustained release of pDNA for 11 days. The released pDNA maintained its structural and functional integrity. Furthermore, the PLGA nanospheres showed lower cytotoxicity than polyethylenimine (PEI) in vitro and in vivo. The nanospheres with vascular endothelial growth factor (VEGF) gene were injected into skeletal muscle of ischemic limb model, and gene expression mediated by the PLGA nanospheres with VEGF gene was compared to that of PEI/pDNA or naked pDNA in vivo. PLGA nanosphere/pDNA had significantly higher VEGF expression levels in comparison to PEI/pDNA and naked pDNA at 12 days after administration. In addition, gene therapy using PLGA nanospheres resulted in more extensive neovascularization at ischemic sites than both naked pDNA and PEI/pDNA. These results indicated that PLGA nanosphere might be useful as a potential carrier for skeletal muscle gene delivery applications.     

Intracellular pathways and nuclear localization signal peptide-mediated gene transfection by cationic polymeric nanovectors

Polyethylenimine (PEI) - based polymers are promising cationic nanovectors. A good understanding of the mechanism by which cationic polymers/DNA complexes are internalized and delivered to nuclei helps to identify which transport steps may be manipulated in order to improve the transfection efficiency. In this work, cell internalization and trafficking of PEI-CyD (PC) composed of β-cyclodextrin (β-CyD) and polyethylenimine (PEI, Mw 600) are studied. The results show that the PC transfected DNA is internalized by binding membrane-associated proteoglycans. The endocytic pathway of the PC particles is caveolae- and clathrin-dependent with both pathways converging to the lysosome. The intracellular fate of the PC provides visual evidence that it can escape from the lysosome. Lysosomal inhibition with chloroquine has no effect on PC mediated transfection implying that blocking the lysosomal traffic does not improve transfection. To improve the nuclear delivery of PC transfected DNA, nuclear localization signal (NLS) peptides are chosen to conjugate and combine with the PC. Compared to PC/pDNA, PC-NLS/pDNA, and PC/pDNA/NLS can effectively improve gene transfection in dividing and non-dividing cells.     

非病毒载体聚乙烯亚胺转基因因素的优化

聚乙烯亚胺属于阳离子多聚物,可浓缩DNA作为转基因非病毒载体。但其转染影响变量较多,如果不能充分控制将不能得到重复的、良好的结果。这里测定了聚乙烯亚胺转基因效率的影响因素,为合成更复杂的人工转基因载体创造条件。我们通过聚乙烯亚胺转染编码β-半乳糖苷酶的pSVβ质粒到CO S-7和N IH 3T 3细胞中,测定质粒因素、血清、细胞密度、操作方式以及转染复合物的保存因素对聚乙烯亚胺转基因效率的影响。结果表明:质粒中生物活性抑制剂明显降低转染效率,通过截流分子量3000或10000的超滤可以除去生活性抑制剂;断裂的质粒降低转染效率;培养液中的血清、白蛋白降低转染效率;细胞密度影响转染效率;PE I/DNA复合物与细胞作用8h后吸去,转染效果最优。冻存显著降低PE I/DNA转染复合物转染效率。聚乙烯亚胺可以作为合成新型非病毒载体的骨架,但必须控制有关因素才能发挥最佳的和可重复性的转染结果。     

The conjugation of diphtheria toxin T domain to poly(ethylenimine) based vectors for enhanced endosomal escape during gene transfection

The endosomal escape is a well-known serious obstacle for non-viral gene delivery. This is because of an acidic and enzymatic degradation of the contents of the endosome/lysosome. Therefore, the internalized gene needs to be efficient released into the cytosol to obtain the efficiently transfection efficiency. On the other hand, the diphtheria toxin T domain fuses with endosome membrane by pH decrease, then enhances the endosomal escape of the diphtheria toxin C fragment. In this study, we constructed diphtheria toxin T domain-conjugated poly(ethylenimine)s (PEI) polyplex for enhancing the endosomal escape of exogenous gene. The conjugation of diphtheria toxin T domain with PEI/pDNA polyplex leads to the significant enhancement of transfection efficiency when compared with plain PEI/pDNA polyplex. The pH-responsive increase in hydrophobicity of the diphtheria toxin T domain might not only trigger the perturbation of the endocytic vesicle membrane but might also increase the membrane permeability.     

Gelatin coating to stabilize the transfection ability of nucleic acid polyplexes

Amphiphilic polymers are effective in complexing and delivering therapeutic nucleic acids, such as plasmid DNA (pDNA) and short interfering RNA (siRNA). However, long-term stability of the complexes is not desirable, as it may have an impact on the transfection efficiency in vivo. To develop a method to preserve complex stability we first showed that pDNA complexes formed with the amphiphilic polymer linoleic acid-substituted polyethylenimine (PEI–LA) and incubated at 37 °C lost ～90% of their transfection efficiency after only 24 h of complex formation. Polyethyleneglycol modification of complexes to control the increase in complex size and incubation in scaffolds used for implantation did not preserve the transfection ability of the complexes. Among a variety of approaches explored, gelatin coating of complexes was found to be the best at maintaining the original transfection efficiency. Mechanistic studies suggested that improved complex uptake, not size stability, was responsible for retention of the transfection efficiency. Similarly to the results with pDNA, gelatin coating also prevented the decreases in uptake and silencing efficiency of siRNA complexes observed following incubation at 37 °C. Gelatin-stabilized complexes were, furthermore, effective in vivo and led to subcutaneous transgene expression with a low pDNA dose that was otherwise ineffective. We conclude that a simple gelatin coating approach offers an efficient means to preserve the transfection efficiency of polyplexes.     

The development of a gene vector electrostatically assembled with a polysaccharide capsule

The purpose of this study was to develop a gene vector electrostatically assembled with a polysaccharide capsule. We used pDNA/polyethylenimine (PEI) complexes as efficient non-viral vectors. The pDNA/PEI complex was electrostatically encapsulated with various polysaccharides such as fucoidan, λ-carrageenan, xanthan gum, alginic acid, hyaluronic acid, and chondroitin sulfate (CS). The pDNA/PEI complex was shown as nanoparticles with positive ζ-potential, although the ternary complexes encapsulated with polysaccharides were shown as nanoparticles with negative ζ-potential. The pDNA/PEI complex showed high agglutination activity and cytotoxicity, although the ternary complexes encapsulated with polysaccharides had no agglutination activities and lower cytotoxicities. The pDNA/PEI complex showed high uptake and high transgene efficiency in B16-F10 cells. On the other hand, most of the ternary complexes show little uptake and gene expression. The ternary complex encapsulated by CS, however, showed comparable transgene efficiency to the pDNA/PEI complex. The uptake and gene expression of the ternary complex encapsulated by CS were significantly inhibited by hypothermia and the addition of CS, suggesting that the ternary complex was taken by CS-specific receptor-mediated energy-dependent process.     

Gene delivery of PEI incorporating with functional block copolymer via non-covalent assembly strategy

A novel functional diblock polymer P(PEGMA-b-MAH) is prepared and incorporated to improve the gene delivery efficiency of poly(ethyleneimine) PEI via non-covalent assembly strategy. First, P(PEGMA-b-MAH) is prepared from l-methacrylamidohistidine methyl ester (MAH) by reversible addition fragmentation chain transfer polymerization, with poly[poly(ethylene glycol) methyl ether methacrylate] (P(PEGMA)) as the macroinitiator. Then P(PEGMA-b-MAH) is assembled with plasmid DNA (pDNA) and PEI (M_w = 10 kDa) to form PEI/P(PEGMA-b-MAH)/pDNA ternary complexes. The agarose gel retardation assay shows that the presence of P(PEGMA-b-MAH) does not interfere with DNA condensation by the PEI. Dynamic light scattering tests show that PEI/P(PEGMA-b-MAH)/pDNA ternary complexes have excellent serum stability. In vitro transfection indicates that, compared to the P(PEGMA-b-MAH) free PEI-25k/pDNA binary complexes, PEI-10k/P(PEGMA-b-MAH)/pDNA ternary complexes have lower cytotoxicity and higher gene transfection efficiency, especially under serum conditions. The ternary complexes proposed here can inspire a new strategy for the development of gene and drug delivery vectors.     

Poly(aspartate-g-PEI800), a polyethylenimine analogue of low toxicity and high transfection efficiency for gene delivery

High-molecular-weight polyethylenimine (25 kDa, PEI25k) is one of the most common cationic polymers utilized in non-viral gene therapy. However, its methylene backbone (-CH(2)CH(2)N(x)-) and high charge density can result in poor biodegradability and high toxicity to cells. We hypothesize that optimizing the polymer length and charge density of PEI analogues may result in decreased toxicity and higher transfection efficiency, and improved biocompatibility in vivo. A series of PEI analogues with controlled molecular weight and charge density were synthesized by grafting low-molecular-weight PEI800 (800 Da) to a polyaspartate peptide backbone of varying degrees of polymerization. The optimum polymer had a degree of polymerization of 65 with an average of 16 PEI800 groups conjugated to it. All of the polycations investigated in the study caused inflammation and apoptosis/necrosis in the liver and spleen of rodents 24h post-injection; however, by day 5, the optimized poly(aspartate-g-PEI800) polymer and PEI800 did not show tissue damage or apoptosis, whereas PEI25k exhibited evidence of apoptosis/necrosis in the kidneys and spleen. Our study points to the need to optimize gene carriers to minimize toxicity, especially important for the safe delivery of therapeutic genes to explicit organs.     

Specific effects of PEGylation on gene delivery efficacy of polyethylenimine: Interplay between PEG substitution and N/P ratio

While an effective non-viral gene carrier, 25 kDa branched polyethylenimine (PEI) is cytotoxic, and decreasing its toxicity while maintaining its functionality is vital. Conjugation of carriers with polyethylene glycol (PEG) is a common approach to decreasing toxicity and improving biodistribution; however, the effect of PEGylation on PEI transfection efficacy is contradictory at present. The aim of this work was to reveal the details of this dependence. Polymers were synthesized by grafting 2 kDa PEG to 25 kDa PEI at multiple ratios. Unlike typical investigations, parallel studies based on either total polymer weight or PEI-backbone weight were employed at the same time for accurate investigation into the specific effects of PEGylation. Polymers were assessed for toxicity and plasmid DNA (pDNA) binding, while polyplexes were formed at various polymer/pDNA weight ratios and monitored by dynamic light scattering (DLS) in the presence of serum. The efficacy of the polyplexes for pDNA delivery and transgene expression in HEK293 cells was assessed by flow cytometry. This approach unexpectedly revealed that increased PEG substitution caused lower toxicity and pDNA-binding on a per total polymer weight basis, but not on a per PEI-backbone weight basis. DLS indicated that high PEGylation prevents an increase in polyplex size in the presence of serum. Plasmid uptake and transgene expression were found to have a complex relationship with PEG substitution, dependent on the polymer/plasmid-DNA weight ratio. PEGylation generally decreased the transfection efficacy of PEI, but under ideal conditions of PEG substitution and polymer/pDNA ratio, PEGylation provided more effective carrier formulations than the native PEI itself.     

PEG- and PDMAEG-Graft-Modified Branched PEI as Novel Gene Vector: Synthesis,Characterization and Gene Transfection

The cytotoxicity of polyethylenimine (PEI) was a dominating obstacle to its application. Introduction of poly(ethylene glycol) (PEG) blocks to PEI is one of the strategies to alleviate the cytotoxocity of PEI. However, it is well known that the transfection efficiency of PEGylated PEI is decreased to some extent compared to the corresponding PEI. Thus, the aim of our study was to enhance the transfection efficiency of PEGylated PEI. A series of tri-block co-polymers, PEG-g-PEI-g-poly(dimethylaminoethyl L-glutamine) (PEG-g-PEI-g-PDMAEG), as novel vectors for gene therapy was synthesized and evaluated. PEG-g-PEI was first obtained by linking PEG and PEI using isophorone diisocyanate (IPDI) as coupling reagent. The anionic co-polymerization of γ-benzyl-L-glutamate N-carboxyanhydride (BLG-NCA) using PEG-g-PEI as a macro-initiator was carried out, followed by aminolysis with 2-dimethylaminoethylamine to obtain the target water-soluble tri-block co-polymer. The structures of the polymers were confirmed by FT-IR and ¹H-NMR. The influence of the molecular weight of PEI and the length of the PDMAEG chain on the physicochemical properties and transfection activity of polymer/DNA was evaluated. All PEI derivates were revealed to compact plasmid DNA effectively to give polyplexes with suitable size (approx. 100 nm) and moderate zeta potentials (10–15 mV) at N/P ratios over 10. The PEG-g-PEI-g-PDMAEG tri-block co-polymers displayed particularly low cytotoxicity, even at high concentration, reflecting an improved safety profile compared to PEI 25k. Gene transfection efficiency of PEG-g-PEI-g-PDMAEG on HeLa in the presence and absence of serum was determined. Remarkably, the transfection activity of PEG-g-PEI (10k)-g-PDMAEG (PPP-4)/DNA polyplex formulations was nearly twofold higher than PEI 25k/DNA formulations in vitro, and the transfection efficiency was less affected by the presence of serum. These results indicated that the synthesized PEG-g-PEI-g-PDMAEG tri-block co-polymers are promising candidates as carriers for gene delivery.     

All-trans-retinoic acid (ATRA)-grafted polymeric gene carriers for nuclear translocation and cell growth control

Polyethyleneimine (PEI)-g-All-trans-retinoic acid (ATRA) (designated as PRA) was synthesized as a gene carrier. ATRA at its low concentration is known to be linked to nuclear translocation and cell cycle control (either proliferation or growth arrest) depending on its binding protein in cells. The cytotoxicity of PRA conjugates was lower than that of PEI and was gradually reduced as increasing ATRA graft ratios. The resulting nanosized and positively charged PRA/pDNA complexes showed lower transfection efficiency than the PEI/pDNA complexes (N/P = 10) against NIH3T3 which is less sensitive to ATRA in cell growth and more sensitive HeLa cells. However, when a mixed gene complex of PEI and PRA was applied in an effort to reduce the ATRA contents, their NIH3T3 transfection evidenced effective nuclear translocation and induced 2- to 4-fold better transfection efficiency as compared with the PEI/pDNA complexes. When the PEI/pDNA complexes were utilized to transfect HeLa cells, free ATRA treatment reduced their cellular uptake and transfection efficiency. These findings show that the NIH3T3 cells against ATRA-mediated growth arrest would not damage the PRA-mediated transfection enhancement resulting from the facilitated nuclear translocation of polyplexes or pDNA. The more ATRA-sensitivity in growth arrest of HeLa cells would reduce the transfection efficiency of ATRA-incorporated polyplexes. The transfection capability of gene by newly synthesized PRA conjugates to cells is differentiated by their ATRA-sensitivity to nuclear translocation and cell growth control.     

Cationic supramolecules consisting of oligoethylenimine-grafted alpha-cyclodextrins threaded on poly(ethylene oxide) for gene delivery

In this study, three cationic polyrotaxanes composed of multiple oligoethylenimine-grafted alpha-cyclodextrin rings threaded on a poly(ethylene oxide) chain have been synthesized and characterized, and investigated for gene delivery. All three cationic polyrotaxanes could efficiently compact pDNA into small nanoparticles, with diameters ranging from 100 to 200 nm. In both BHK-21 and MES-SA cell lines, the transfection efficiency mediated by the cationic polyrotaxanes were comparable or even higher than that of branched polyethylenimine (PEI) with a molecular weight of 25 kDa, which is one of the most efficient gene-delivery vectors to date. Moreover, the cationic polyrotaxanes showed much lower cytotoxicity than branched PEI (25 kDa). Hence, these cationic poly rotaxanes have high potentials as new carriers for gene delivery.     

FGF receptor-mediated gene delivery using ligands coupled to polyethylenimine

To obtain new nonviral vectors with high gene delivery efficiency and special cell targeting ability, an attractive strategy is to link ligands to polyethylenimine (PEI). Fibroblast growth factor receptors (FGFRs) are highly expressed on a variety of human cancer cells and are potential targets for cancer gene therapy. In this study, the peptides NH2-Met-Gln-Leu-Pro-Leu-Ala-ThrGly-Gly-Gly-Cys-COOH (MC11) which have been proved to combine specially with the FGFR on cell membrane are coupled to PEI using N-Succinimidyl-3-(2-pyridyldithio) propionate (SPDP) as a linker with different molar ratios (1 : 0.3, 1 : 0.75, 1 : 1.5, and 1 : 3.0) and the new polymer PEI-MC11 is verified by a series of physicochemical methods including 1H-NMR and FTIR. The agarose gel electrophoresis assay, particle size test, zeta potential test, and electron microscope observation show that PEI-MC11 can efficiently condense plasmid DNA into nanoparticles with about 200 nm in diameter and with positive surface charge at the suitable N/P ratio. The MTT assay suggests the decreased toxicity of the polymers. The results of the gene delivery efficiency in vitro show that PEI-MC11/pDNA polyplexes have significantly greater transgene activity than PEI/pDNA in COS-7 and HepG2 cells which express FGFR positively, while no such effect is observed in PC3 cells which have negative FGFR. The enhanced gene delivery efficiency of PEI-MC11 can be blocked by the co-culture of free peptides MC11 before the gene delivery procedure. The synthesized nonviral vector based on PEI with the targeting peptides MC11 for binding FGFR has improved efficiency of gene delivery and targeting specificity in FGFR positive cells. It may have potential application in cancer gene therapy.     

Structure–transfection activity relationships with glucocorticoid–polyethyl-enimine conjugate nuclear gene delivery systems

Efficient nuclear gene delivery is essential for successful gene therapy. It was previously reported that the transport of DNA into nucleus may be facilitated by glucocorticoid (GC). In this study, five glucocorticoids with different structures and potencies were conjugated with low molecular weight PEI 1800, and the degree of substitution of glucocorticoids was controlled to be close to each other. The glucocorticoid–polyethylenimine (GC–PEI)/pDNA complexes were prepared and their physico-chemical properties and transfection efficiency were investigated. The results showed that the complexes had similar physico-chemical properties, but their transfection activities were different statistically. In order to explore the reason of this difference, the affinity of GC–PEI polymer with GC receptor was analyzed by the application of molecular docking, and the correlation between transfection activity and the potency of five GC was investigated. The result showed that receptor binding of five GC was different and transgene expression enhanced linearly with the increasing GC potency, but log P. In addition, confocal microscopy examination confirmed that GC–PEI/DNA complexes were more effectively translocated in the nucleus than PEI 25 K or PEI 1800 complexes and the cytotoxicities of the GC–PEI polymers were lower than that of PEI 25 K. These results demonstrated that transfection activity of GC–PEI polymer correlated with its GC potency, and this regularity might be useful for the development of more efficient GC substituted polymer as promising nuclear-targeting carrier.