Nuclear localization signal peptide enhances transfection efficiency and decreases cytotoxicity of poly(agmatine/N,N′-cystamine-bis-acrylamide)/pDNA complexes

At present, nonviral gene vectors develop rapidly, especially cationic polymers. A series of bioreducible poly(amide amine) (PAA) polymers containing guanidino groups have been synthesized by our research team. These novel polymer vectors demonstrated significantly higher transfection efficiency and lower cytotoxicity than polyethylenimine (PEI)—25kDa. However, compared with viral gene vectors, relatively low transfection efficiency, and high cytotoxicity are still critical problems confronting these polymers. In this study, poly(agmatine/N,N′-cystamine-bis-acrylamide) p(AGM-CBA) was selected as a model polymer, nuclear localization signal (NLS) peptide PV7 (PKKKRKV) with good biocompatibility and nuclear localization effect was introduced to investigate its impact on transfection efficiency and cytotoxicity. NLS peptide-mediated in vitro transfection was performed in NIH 3T3 cells by directly incorporating NLS peptide with the complexes of p(AGM-CBA)/pDNA. Meanwhile, the transfection efficiency and cytotoxicity of these complexes were evaluated. The results showed that the transfection efficiency could be increased by 5.7 times under the appropriate proportion, and the cytotoxicity brought by the polymer vector could be significantly reduced.     

Design and biophysical characterization of bioresponsive degradable poly(dimethylaminoethyl methacrylate) based polymers for in vitro DNA transfection

Water-soluble, degradable polymers based on poly(N,N-dimethylaminoethyl methacrylate) (PDMAEMA) with low cytotoxicity and good p-DNA transfection efficiency are highlighted in this article. To solve the nondegradability issue of PDMAEMA, new polymers based on DMAEMA and 5,6-benzo-2-methylene-1,3-dioxepane (BMDO) for gene transfection were synthesized. A poly(ethylene oxide) (PEO) azo-initiator was used as free-radical initiator. PEGylation was performed to improve water solubility and to reduce cytotoxicity of the polymers. The resulting polymers contain hydrolyzable ester linkages in the backbone and were soluble in water even with very high amounts of ester linkages. These degradable copolymers showed significantly less toxicity with a MTT assay using L929 cell lines and demonstrated promising DNA transfection efficiency when compared with the gold standard poly(ethyleneimine). Bioresponsive properties of the corresponding quaternized DMAEMA based degradable polymers were also studied. Although the quaternized DMAEMA copolymers showed enhanced water solubility, they were inferior in gene transfection and toxicity as compared to the unquaternized copolymers.     

Synthesis and characterization of poly (amino ester) for slow biodegradable gene delivery vector

Many therapeutic carrier materials were exploited for human gene therapy from viral to polymeric vectors. This research describes the evaluation of two biodegradable ester-bonded polymers synthesized by double-monomer polycondensation for a non-viral cationic polymer-based gene delivery system. The backbone was constructed to include inner tertiary amines and outer primary amines. Self-assembly with DNA resulted in the production of regularly nano-sized spherical polyplexes with good transfection efficiency, especially in the presence of serum. The polymers showed a relatively slow degradability for an amine-containing ester polymer, as they maintained DNA/polymer complex for 7 days in physiological buffer conditions. Finally, the low toxicity and slow degradation concluded these polymers reliable for long-term therapeutic applications.     

Synthesis and characterization of folate-PEG-grafted-hyperbranched-PEI for tumor-targeted gene delivery

A great challenge for gene therapy is to develop a high efficient gene delivery system with low toxicity. Nonviral vectors are still attractive although the current agents displayed some disadvantages (i.e., low transfection efficiency, high toxicity). To overcome the high toxicity of poly(ethylene imine) (PEI) and low transfection efficiency of PEGylated PEI (PEG-PEI), we linked a cell specific target molecule folate (FA) on poly(ethylene glycol) (PEG) and then grafted the FA-PEG onto hyperbranched PEI 25 kDa. The FA-PEG- grafted-hyperbranched-PEI (FA-PEG-PEI) effectively condensed plasmid DNA (pDNA) into nanoparticles with positive surface charge under a suitable N/P ratio. Tested in deferent cell lines (i.e., HEK 293T, glioma C6 and hepatoma HepG2 cells), no significant cytotoxicity of FA-PEG-PEI was added to PEG-PEI. More importantly, significant transfection efficiency was exhibited in FA-targeted cells. Reporter assay showed that FA-PEG-PEI/pDNA complexes had significantly higher transgene activity than that of PEI/pDNA in folate-receptor (FR) positive (HEK 293T and C6) cells but not FR-negative (HepG2) cells. These results indicated that FA-PEG-PEI might be a promising candidate for gene delivery with the characteristics of good biocompatibility, potential biodegradability, and relatively high gene transfection efficiency.     

Development and evaluation of a novel nano‐scale vector for siRNA

To synthesize a lipid‐cationic polymer (LCP) containing brassidic acid side chain and to investigate its transfection efficiency and characteristics as a siRNA gene vector. The LCP was chemically synthesized and its nucleic acid binding capacity was determined by gel electrophoresis. HeLa‐EGFP and TH1080‐EGFP cell lines were transfected with siRNA against enhanced green fluorescent protein (EGFP) gene using a LCP to investigate the transfection efficiency. An MTT assay was performed to evaluate the cellular toxicity of the LCP vector. Its degradability and stability under acidic conditions were also investigated. The LCP vector possessed high DNA binding capacity. More than 73% of the cellular fluorescence was inhibited by the LCP‐mediated transfection of siRNA against EGFP gene, indicating that vector had high transfection efficiency. Cellular viability was about 95% at the optimum transfection efficiency of LCP, suggesting that the cellular toxicity of LCP was very low. The LCP was also observed to be degradable; moreover, it could be easily stored at normal temperature. A gene vector used for the transfection of siRNA was successfully fabricated from synthesized LCP. Its numerous excellent properties entitle values for further scientific research. J. Cell. Biochem. 111: 881–888, 2010. © 2010 Wiley‐Liss, Inc.     

PCL film surfaces conjugated with P(DMAEMA)/gelatin complexes for improving cell immobilization and gene transfection

Successful gene transfection on a tissue scaffold is of crucial importance in facilitating tissue repair and regeneration by enabling the localized production of therapeutic drugs. Polycaprolactone (PCL) has been widely adopted as a scaffold biomaterial, but its unfavorable cell-adhesion property needs to be improved. In this work, the PCL film surface was conjugated with poly((2-dimethyl amino)ethyl methacrylate) (P(DMAEMA))/gelatin complexes via surface-initiated atom transfer radical polymerization (ATRP) for improving cell immobilization and subsequent gene transfection. A simple aminolysis-based method was first used for the covalent immobilization of ATRP initiators on the PCL film. Well-defined P(DMAEMA) brushes were subsequently prepared via surface-initiated ATRP from the initiator-functionalized PCL surfaces. The P(DMAEMA) chains with a pK(a) of 7.0-7.3 were used for conjugating gelatin with a pI of 4.7 via electrostatic interaction. The amount of complexed gelatin increased as that of the grafted P(DMAEMA) layer. The cell-adhesion property on the functionalized PCL surface could be controlled by adjusting the ratio of P(DMAEMA)/gelatin. It was found that the gene transfection property on the immobilized cells was dependent on the density of the immobilized cells on the functionalized PCL film. With the good cell-adhesive nature of gelatin and the efficient gene transfection on the dense immobilized cells, the incorporating the suitable of P(DMAEMA)/gelatin complexes onto PCL surfaces could endow the PCL substrates new and interesting properties for potential tissue engineering applications.     

Biodegradable cationic polyester as an efficient carrier for gene delivery to neonatal cardiomyocytes

Viral-mediated gene delivery has been explored for the treatment and protection of cardiomyocytes, but so far there is only one report using cationic polymer for gene delivery to cardiomyocytes in spite of many advantages of polymer-mediated gene delivery. In this study, a cationic poly(beta-amino ester) (PDMA) with a degradable backbone and cleavable side chains was synthesized by Michael addition reaction. The toxicity of PDMA to neonatal mouse cardiomyocytes (NMCMs) was significantly lower than that of polyethyleneimine (PEI). PDMA formed stable polyplexes with pEGFP. The dissociation of the polyplexes could be triggered by PDMA degradation, and the dissociation time was tunable via the polymer/pEGFP ratio. In vitro transfection showed that PDMA was an effective and low toxic gene delivery carrier for NMCMs. The PDMA/pEGFP polyplexes transfected EGFP gene to NMCMs with about 28% efficiency and caused little death. In contrast, a significant portion of cardiomyocytes cultured with PEI/pEGFP died.     

pH-responsive three-layered PEGylated polyplex micelle based on a lactosylated ABC triblock copolymer as a targetable and endosome-disruptive nonviral gene vector

Nonviral vectors for gene therapy have recently received an increased impetus because of the inherent safety problems of the viral vectors, while their transfection efficiency is generally low compared to the viral vectors. The lack of the ability to escape from the endosomal compartments is believed to be one of the critical barriers to the intracellular delivery of noviral gene vectors. This study was devoted to the design and preparation of a novel ABC triblock copolymer for constructing a pH-responsive and targetable nonviral gene vector. The copolymer, lactosylated poly(ethylene glycol)-block-poly(silamine)-block-poly[2-(N,N-dimethylamino)ethyl methacrylate] (Lac-PEG-PSAO-PAMA), consists of lactosylated poly(ethylene glycol) (A-segment), a pH-responsive polyamine segment (B-segment), and a DNA-condensing polyamine segment (C-segment). The Lac-PEG-PSAO-PAMA spontaneously associated with plasmid DNA (pDNA) to form three-layered polyplex micelles with a PAMA/pDNA polyion complex (PIC) core, an uncomplexed PSAO inner shell, and a lactosylated PEG outer shell, as confirmed by 1H NMR spectroscopy. Under physiological conditions, the Lac-PEG-PSAO-PAMA/pDNA polyplex micelles prepared at an N/P (number of amino groups in the copolymer/number of phosphate groups in pDNA) ratio above 3 were found to be able to condense pDNA, thus adopting a relatively small size (< 150 nm) and an almost neutral surface charge (zeta approximately +5 mV). The micelle underwent a pH-induced size variation (pH = 7.4, 132.6 nm --> pH = 4.0, 181.8 nm) presumably due to the conformational changes (globule-rod transition) of the uncomplexed PSAO chain in response to pH, leading to swelling of the free PSAO inner shell at lowered pH while retaining the condensed pDNA in the PAMA/pDNA PIC core. Furthermore, the micelles exhibited a specific cellular uptake into HuH-7 cells (hepatocytes) through asialoglycoprotein (ASGP) receptor-mediated endocytosis and achieved a far more efficient transfection ability of a reporter gene compared to the Lac-PEG-PSAO/pDNA and Lac-PEG-PAMA/pDNA polyplex micelles composed of the diblock copolymers and pDNA. The effect of hydroxychloroquine as an endosomolytic agent on the transfection efficiency was not observed for the Lac-PEG-PSAO-PAMA/pDNA polyplex micelles, whereas the nigericin treatment of the cell as an inhibitor for the endosomal acidification induced a substantial decrease in the transfection efficiency, suggesting that the protonation of the free PSAO inner shell in response to a pH decrease in the endosome might lead to the disruption of the endosome through buffering of the endosomal cavity. Therefore, the polyplex micelle composed of ABC (ligand-PEG/pH-responsive segment/DNA-condensing segment) triblock copolymer would be a promising approach to a targetable and endosome disruptive nonviral gene vector.     

Novel biodegradable poly(disulfide amine)s for gene delivery with high efficiency and low cytotoxicity

Novel biodegradable poly(disulfide amine)s with defined structure, high transfection efficiency, and low cytotoxicity were designed and synthesized as nonviral gene delivery carriers. Michael addition between N, N'-cystaminebisacrylamide (CBA) and three N-Boc protected diamines ( N-Boc-1,2-diaminoethane, N-Boc-1,4-diaminobutane, and N-Boc-1,6-diaminohexane) followed by N-Boc deprotection under acidic condition resulted in final cationic polymers with disulfide bonds, tertiary amine groups in main chains, and pendant primary amine groups in side chains. Polymer structures were confirmed by 1H NMR, and their molecular weights were in the range 3.3-4.7 kDa with narrow polydispersity (1.12-1.17) as determined by size exclusion chromatography (SEC). Acid-base titration assay showed that the poly(disulfide amine)s possessed superior buffering capacity to branched PEI 25 kDa in the pH range 7.4-5.1, which may facilitate the escape of DNA from the endosomal compartment. Gel retardation assay demonstrated that significant polyplex dissociation was observed in the presence of 5.0 mM DTT within 1 h, suggesting rapid DNA release in the reduction condition such as cytoplasm due to the cleavage of disulfide bonds. Genetic transfections mediated by these poly(disulfide amine)s were side-chain spacer length dependent. The poly(disulfide amine) with a hexaethylene spacer, poly(CBA-DAH), had comparable transfection efficiency to bPEI 25 kDa in the tested cell lines, i.e., 293T cells, Hela cells, and NIH3T3 cells. This same poly(disulfide amine) mediated 7-fold higher luciferase expression than bPEI 25 kDa in C2C12 cells (mouse myoblast cell line), a cell line difficult to transfect with many cationic polymers. Furthermore, MTT assay indicated that all three poly(disulfide amine)s/pDNA polyplexes were significantly less toxic than bPEI/pDNA complexes.     

Biodegradable poly(vinyl alcohol)-polyethylenimine nanocomposites for enhanced gene expression in vitro and in vivo

Use of cationic polymers as nonviral gene vectors has several limitations such as low transfection efficiency, high toxicity, and inactivation by serum. In this study, varying amounts of low molecular weight branched polyethylenimine 1.8 kDa (bPEI 1.8) were introduced on to a neutral polymer, poly(vinyl alcohol) (PVA), to bring in cationic charge on the resulting PVA-PEI (PP) nanocomposites. We rationalized that by introducing bPEI 1.8, buffering and condensation properties of the proposed nanocomposites would result in improved gene transfer capability. A series of PVA-PEI (PP) nanocomposites was synthesized using well-established epoxide chemistry and characterized by IR and NMR. Particle size of the PP/DNA complexes ranged between 120 to 135 nm, as determined by dynamic light scattering (DLS), and DNA retardation assay revealed efficient binding capability of PP nanocomposites to negatively charged nucleic acids. In vitro transfection of PP/DNA complexes in HEK293, HeLa, and CHO cells revealed that the best working formulation in the synthesized series, PP-3/DNA complex, displayed ~2-50-fold higher transfection efficiency than bPEIs (1.8 and 25 kDa) and commercial transfection reagents. More importantly, the PP/DNA complexes were stable over a period of time, along with their superior transfection efficiency in the presence of serum compared to serum-free conditions, retaining the nontoxic property of low molecular weight bPEI. The in vivo administration of PP-3/DNA complex in Balb/c mice showed maximum gene expression in their spleen. The study demonstrates the potential of PP nanocomposites as promising nonviral gene vectors for in vivo applications.     

Degradable-brushed pHEMA-pDMAEMA synthesized via ATRP and click chemistry for gene delivery

Brushed polymers composed of a backbone of poly(hydroxyethyl methacrylate) (pHEMA) onto which poly(2-(dimethylamino)ethyl methacrylate)s (pDMAEMAs) was grafted via a hydrolyzable linker were synthesized and evaluated as nonviral gene delivery vectors. Both pDMAEMA and pHEMA polymers with controlled molecular weights and narrow distributions were synthesized by controlled atom transfer radical polymerization (ATRP). The azide initiator was used to ensure complete and monoazide functionalization of the pDMAEMA polymer chains. Click reaction between pHEMA with alkyne side groups and the azide end group in the pDMAEMA resulted in a high-molecular-weight polymer composed of low-molecular-weight constituents via an easily degradable carbonate ester linker. The length of the pDMAEMA grafts as well as the number of grafts of the brushed pHEMA-pDMAEMA can be easily varied. At physiological conditions (pH 7.4 and 37 degrees C), the brushed polymer degraded by hydrolysis of the carbonate ester with a half-life of 96 h. The molecular weights of the formed degradation products was very close to that of the starting pDMAEMA, which is likely below the renal excretion limit (<30 kDa). It was shown that the degradable brushed pHEMA-pDMAEMAs were able to condense plasmid DNA into positively charged nanosized particles. The resulting polyplexes were able to transfect cells efficiently in the presence of the endosomal membrane disrupting INF-7 peptide, and all these degradable polymers showed lower cellular toxicity compared to a high-molecular-weight pDMAEMA reference. On the other hand, the low-molecular-weight pDMAEMA used for the grafting to pHEMA was neither able to condense the structure of DNA nor able to transfect cells. This study demonstrates that grafting a low-molecular-weight cationic polymer via a hydrolyzable linker to a neutral hydrophilic polymer is an effective approach to modulate the transfection activity and toxicity profile of gene delivery polymers.     

Synthesis and characterization of new permanently charged poly(amidoammonium) salts and evaluation of their DNA complexes for gene transport

A new series of linear and permanently charged poly(amidoammonium) salts were synthesized in order to investigate the influence of their ionic and hydrophobic contents on both the cytotoxicity and the transfection mediated by polycation-DNA complexes. The poly(amidoammonium) salts were prepared by chemical modification of a parent poly(amidoamine) containing two tertiary amino groups per structural unit: one incorporated into the main chain and the other fixed at the end of a short bismethylene spacer. The permanent charges were introduced through a quaternization reaction involving iodomethane or 1-iodododecane as an alkylating agent. Under appropriate conditions, the methylation reaction was found to be regioselective, allowing the quaternization of either the side chains or both the side chains and the backbone. Under physiological salt conditions (150 mM NaCl), all of the poly(amidoammonium) salts self-assembled with DNA to form complexes. High proportions of highly quaternized polycation provided better defined morphology to the polycation-DNA complexes. Complexes formed from unquaternized polycation were less cytotoxic than branched poly(ethyleneimine) (25 kDa). At high polycation-DNA weight ratios, the introduction of permanent charges generated a significant increase in the cytotoxicity, but no patent correlation could be established with the amount and the position of the permanent charges. Only complexes formed from polycations with quaternized backbone were able to generate significant gene expression, which was putatively attributed to a better defined toroidal-like morphology together with a higher stability, as suggested by zeta potential measurements. The incorporation of dodecane side chains on highly charged polycations severely amplified the cytotoxicity so that, in return, the transfection level was dramatically affected.     

Synthesis of poly(amidoamine) dendron-bearing lipids with poly(ethylene glycol) grafts and their use for stabilization of nonviral gene vectors

Recently, we developed a new type of cationic lipid that consists of an amine-terminated poly(amidoamine) dendron and two long alkyl groups. These dendron-bearing lipids achieved efficient gene transfection of cells through synergetic action of the proton sponge effect and membrane fusion in combination with fusogenic lipid dioleoylphosphatidylethanolamine. Using those dendron-bearing lipids as a base material, we developed in this study a functional component of gene vectors that stabilizes lipoplexes by multiple PEG chains and promotes gene transfection through the proton sponge effect. We combined a poly(ethylene glycol) (PEG, 550 Da) graft to each of four chain ends of the G2 dendron-bearing lipid (P4-DL). An analogous molecule having single PEG graft was also synthesized using the G0 dendron-bearing lipid (P1-DL). Inclusion of P4-DL decreased the size of the G3 dendron-bearing lipid-based lipoplexes more efficiently than P1-DL. In addition, P4-DL-containing lipoplexes exhibited two-orders-higher transfection efficiency than P1-DL-containing lipoplexes with the same PEG graft density. These results indicate the superiority of multiple attachments of PEG graft chains to a lipid for heightened ability to increase colloidal stability of lipoplexes while retaining their transfection activity. The lipoplexes stabilized by P4-DL were small, around 250 nm, and achieved efficient transfection in the presence of serum. Therefore, P4-DL and its analogues will form the basis for production of efficient nonviral vectors for in vivo use.     

Poly(DMAEMA-NVP)-b-PEG-galactose as gene delivery vector for hepatocytes

A block copolymer composed of cationic polymer and poly(ethylene glycol) (PEG) was used as a DNA carrier. Poly(2-(dimethylamino)ethyl methacrylate (DMAEMA)-co-N-vinyl-2-pyrrolidone (NVP)) having a terminal carboxylic group was synthesized by free radical polymerization using an initiator, 4,4'-azobis(4-cyanovaleric acid). The terminal carboxylic acid was activated by N-hydroxysuccinimide (NHS) with dicyclohexylcarbodiimide (DCC) and then conjugated with PEG-bis(amine). For specific gene targeting to asialoglycoprotein receptor of hepatocytes, a galactose moiety was incorporated into the PEG terminal end of poly(DMAEMA-NVP)-b-PEG by reductive coupling using lactose and sodium cyanoborohydride. RSV luciferase plasmid was used as a reporter gene, and in vitro gene transfection efficiency was measured in HepG2 human hepatocarcinoma cells. Poly(DMAEMA-NVP)-b-PEG-galactose/DNA complexes formed at 0.5-2 polymer/plasmid weight ratio had compacted structures around 200 nm particle size and exhibited slightly negative surface charge. These complexes were coated with a cationic, pH sensitive, endosomolytic peptide, KALA, to generate positively charged poly(DMAEMA-NVP)-b-PEG-galactose/DNA/KALA complex particles. In the presence of serum proteins, both the PEG block and the galactose moiety of poly(DMAEMA-NVP)-b-PEG-galactose greatly enhanced the gene transfection efficiency, which was very close to that of Lipofectamine plus. Irrespective of the presence of serum proteins, as the KALA/DNA weight ratio increased, the transfection efficiency of poly(DMAEMA-NVP)-b-PEG-galactose was enhanced due to the pH dependent endosomal disruptive property of KALA. This study demonstrates that sufficient transfection efficiency as high as that of commercial agent could be attained by judicious formulation of molecular engineered poly(DMAEMA-NVP)-b-PEG-galactose in combination with an endosomolytic peptide, KALA.     

Correlating transfection barriers and biophysical properties of cationic polymethacrylates

Transfection efficiencies of several polymeric gene carriers were compared and correlated quantitatively to the amounts of cellular accumulation of plasmid DNA and to the expression of mRNA by quantitative real-time polymerase chain reaction (real-time PCR). Three polycations polymers with similar chemical structure were used in this study: poly(dimethylamino)ethyl methacrylate (PDMA) homopolymer, PEO-b-PDMA copolymer, and PEO-b-poly(diethylamino)ethyl methacrylate (PEO-b-PDEA) copolymer. Despite their similar chemical structures, the transfection efficiencies were significantly different. PEO-b-PDEA copolymer was significantly less efficient as gene carrier as compared to both PDMA and PEO-b-PDMA. Correlations between cytotoxicity, cellular uptake of plasmid DNA, expression levels of transgene and protein, and the physical properties of the polymers were observed. With the PEO-b-PDEA studies, cytotoxicity was due primarily to the excess of polymers that did not participate in the DNA binding. In addition, the inability of the polymer/DNA polyplexes to interact with cell effectively was identified as a critical barrier for high efficiency of transfection. This study demonstrated that the use of quantitative real-time PCR in combination with physical characterization techniques could provide useful insights into the transfection barrier at different cellular levels.     

Lipopolythiourea transfecting agents: lysine thiourea derivatives

Synthetic vectors represent an alternative to recombinant viruses for gene transfer. We have recently explored the transfection potential of a class of noncationic lipids bearing thiourea moieties as DNA-associating headgroups. The encouraging results obtained with lipopolythioureas derived from serinol prompted us to further investigate this family of vectors. In the present study, we considered the transfection properties of a series of derivatives based on a different thiourea polar headgroup bearing a lysine scaffold. The synthesis of these compounds could be readily achieved in three steps with good yields. We found that these lipopolythioureas (LPT) might be considered as alternative systems for gene transfection since their activity reached the same magnitude range as that of cationic vectors in the presence of serum. LPT with 14-carbon length chains appeared to be more efficient as a transfecting agent than the ones with shorter chains. Toxicity studies proved that the hydration film method led to particles well tolerated both by the cells in vitro and by the mice in vivo. The ability to induce gene expression in vivo was demonstrated by intratumoral injection. Finally, biodistribution studies showed that the quantity recovered in blood circulation, 2 h after systemic injection, was improved as compared to that in cationic lipids.     

Influence of polymer architecture and molecular weight of poly(2-(dimethylamino)ethyl methacrylate) polycations on transfection efficiency and cell viability in gene delivery

Nonviral gene delivery with the help of polycations has raised considerable interest in the scientific community over the past decades. Herein, we present a systematic study on the influence of the molecular weight and architecture of poly(2-(dimethylamino)ethyl methacrylate) (PDMAEMA) on the transfection efficiency and the cytotoxicity in CHO-K1 cells. A library of well-defined homopolymers with a linear and star-shaped topology (3- and 5-arm stars) was synthesized via atom transfer radical polymerization (ATRP). The molecular weights of the polycations ranged from 16 to 158 kDa. We found that the cytotoxicity at a given molecular weight decreased with increasing number of arms. For a successful transfection a minimum molecular weight was necessary, since the polymers with a number-average molecular weight, M(n), below 20 kDa showed negligible transfection efficiency at any of the tested polyelectrolyte complex compositions. From the combined analysis of cytotoxicity and transfection data, we propose that polymers with a branched architecture and an intermediate molecular weight are the most promising candidates for efficient gene delivery, since they combine low cytotoxicity with acceptable transfection results.     

PDEA-coated magnetic nanoparticles for gene delivery to Hep G2 cells

Poly(2-(diethylamino)ethyl methacrylate) coated magnetic nanoparticles (PDEA-MNPs) were synthesized as a new gene nanocarrier to delivery plasmids (pEGFPN1 and pRL-TK) into human hepatoma (Hep G2) cells. The PDEA-MNPs shows the pH-sensitive property. These nanoparticles are positively charged at acidic pH and negatively charged at neutral or alkaline pH. The PDEAMNPs exhibited a low cytotoxicity in Hep G2 cells. PDEA-MNPs could bind and protect DNA from DNase I degradation. The transfection study demonstrated that the PDEA-MNPs could carry plasmid into Hep G2 cells and exhibited a high gene transfection efficiency. These results indicated that the novel magnetic nanoparticles could enhance gene transfection in vitro and hold the potential to be a promising non-viral nanodevice.     

Biodegradable,endosome disruptive,and cationic network-type polymer as a highly efficient and nontoxic gene delivery carrier

The success of gene therapy is largely dependent on the delivery vector system. Efficient transfection and nontoxicity are two of the most important requirements of an ideal gene delivery vector. To generate both an efficient and nontoxic vector, we rationally constructed polymeric vectors to have simultaneous multiple functions, i.e., controlled degradation, an endosome disruptive function, and positive charges. Remarkably, the transfection efficiency of network poly(amino ester) (n-PAE) synthesized in this manner was comparable to that of polyethylenimine (PEI), one of the most efficient polymeric gene delivery vectors reported to date. However, there was a marked difference in cytotoxicity between the polymers. The majority of PEI-transfected cells were granulated and dead, whereas most of the cells transfected with n-PAE were viable and healthy. Successive events of efficient endosome escape of n-PAE/DNA polyplex and n-PAE biodegradation should result in high transfection efficiency and favorable cell viability response. The n-PAE-mediated transfection was also very efficient in the presence of serum. These data show that the approach we applied is a very appropriate way of making an ideal gene delivery carrier.