Chitosan–DNA Nanoparticles: Effect on DNA Integrity,Bacterial Transformation and Transfection Efficiency

While somatic gene therapy has the potential to treat many genetic disorders, recent clinical trials suggest that an efficient and safe delivery vehicle for successful gene therapy is lacking. The current study examines the influence of two different preparation (the solvent evaporation method and the complex coacervation method) methods on the encapsulation of a model plasmid with chitosan. The ability of different molecular weights of chitosan to form nanoparticles with a plasmid, and particulated polymers to stabilize a plasmid in a supercoiled form, were examined by agarose gel electrophoresis. Protection of encapsulated pDNA offered by these nanoparticles from nuclease attack was confirmed by assessing degradation in the presence of DNase I, and the transformation of the plasmids with incubated nanoparticles were examined by β-galactosidase assay. Model pDNA existed as a mixture of both supercoiled (84.2%) and open circular (15.8%) forms. Our results demonstrated that supercoiled forms decreased while open circular forms and fragmented linear forms increased during the preparation of formulations. F1 formulation prepared by the complex coacervation method protected the supercoiled form of pDNA effectively. There weren't any significant changes in nanoparticle size and zeta potential values at pH 5.5 for a period of 3 months, but differences in particle sizes were observed after lyophilization with a cryoprotective agent. The efficiency of nanoparticles mediated transformation to Escherichia coli cells was significantly higher than naked DNA or poly-_l-lysine (PLL)–DNA polycation complexes. The transfection studies were performed in COS-7 cells. A 3-fold increase in gene expression was produced by nanoparticles as compared to the same amount of naked plasmid DNA (pDNA). These observations suggest that formulations with high molecular weight (HMW) chitosan can be an effective non-viral method of gene vector in animal studies.     

Association and Dissociation Characteristics of Polymer/DNA Complexes Used for Gene Delivery

Purpose. The DNA association/dissociation properties of water-soluble cationic methacrylate polymers with closely related structures (poly(2-dimethylamino)ethyl methacrylate) [p(DMAEMA)], poly(2-(trimethylamino)ethyl methacrylate chloride) [p(TMAEMA)]) and the frequently used transfectant poly(L-lysine) were studied to gain a better insight into their transfection characteristics. Methods. Association of DNA with different polymers and dissociation of the complexes, achieved by adding an excess of anionic polymers or salt, were studied by using spectroscopic techniques (fluorescence, circular dichroism (CD)), agarose gel electrophoresis and an enzymatic assay (DNase I treatment). The transfection efficiency of the polyplexes was evaluated in tissue culture with OVCAR-3 cells. Results. Plasmid DNA complexed with either poly(L-lysine) or p(DMAEMA) was protected against digestion by DNase I. Fluorescence and CD spectroscopy as well as gel electrophoresis revealed that p(DMAEMA) with a relatively high molecular weight and poly(L-lysine) have similar DNA association/dissociation characteristics. Therefore, differences in transfection potential of the polyplexes cannot be ascribed to differences in binding characteristics, but are probably caused by other factors. As compared with the other polymers, p(TMAEMA) has a high affinity for DNA as was concluded from the observation that poly(aspartic acid) was unable to fully dissociate complexes containing this polymer. This fact might very well explain the low transfection efficiency of these polyplexes. p(DMAEM A) with a relatively low molecular weight probably has a low affinity for DNA, which might explain both the formation of DNA aggregates -DNA) and the low transfection potential obtained when using this polymer. Conclusions. DNA association/dissociation studies shed light on the preferred characteristics of polymeric transfectants.     

Targeting delivery of oligonucleotide and plasmid DNA to hepatocyte via galactosylated chitosan vector

Delivery of oligonucleotide to specific cells and maintenance of its biological function are important for nucleic acid therapy. The objective of this paper is to demonstrate that galactosylated low molecular weight chitosan (gal-LMWC) is a safe and effective vector of antisense oligonucleotide (ASO) and plasmid DNA for the hepatocyte targeting delivery. Gal-LMWC has been successfully prepared and MTT cytotoxic assay shows that cytotoxicity of gal-LMWC is lower than that of high molecular weight chitosan (HMWC) and low molecular weight chitosan (LMWC) in HepG2 cells. Using a complex coacervation process, gal-LMWC can form stable nano-complexes with plasmid DNA or with ASO by the electrostatic interaction. The morphometrics, particle size, and the zeta potential of gal-LMWC/ASO complexes and gal-LMWC/plasmid DNA complexes are very similar. The transfection efficiency by using gal-LMWC vector is significantly higher than that of naked DNA or naked ASO in HepG2 cells. Transfection efficiency of gal-LMWC/ASO complexes and gal-LMWC/plasmid DNA complexes depends on the molar ratio of the positive chitosan amino group and the negative DNA phosphate group (N/P ratio) strongly. Inhibition experiments confirm that the enhanced transfection efficiency is due to the ASGR mediated endocytosis of the gal-LMWC/ASO complexes or gal-LMWC/DNA complexes. These results suggest that gal-LMWC can be used in gene therapy to improve the transfection efficiency in vitro and in vivo.     

Galactosylated low molecular weight chitosan as DNA carrier for hepatocyte-targeting

Chitosan has the potential for DNA complexation and is useful as a non-viral vector for gene delivery. Highly purified low molecular weight chitosan (LMWC) was prepared. Lactobionic acid (LA) bearing galactose group was coupled with LMWC for liver-specificity. A series of galactosylated-LMWC (gal-LMWC) samples covering a range of galactose group contents were prepared. The chitosan/DNA complexes were obtained using a complex coacervation process. Gal-LMWCs were used to transfer pSV-beta-galactosidase reporter gene into human hepatocellular carcinoma cell (HepG2), L-02, SMMC-7721, and human cervix adenocarcinoma cell line (HeLa) cell lines in vitro. Transfection efficiency of gal-LMWCs was evaluated by beta-galactosidase assay and compared with those of lipofectin, calcium phosphate (CaP), high molecular weigh chitosan (HMWC) and LMWC. Gal-LMWC/DNA complex shows a very efficient cell selective transfection to hepatocyte. The transfection efficiency of gal-LMWCs increased with the improvement of the galactosylation degree. Cytotoxicity of gal-LMWC was determined by 3-(4,5-dimethylthiazd-2-yl)-2,5-diphenyltentrazolium bromide (MTT) assay and the results show that the modified chitosan has relatively low cytotoxicity, giving the evidence that the modified chitosan vector has the potential to be used as a safe gene-delivery system.     

Drying of a plasmid containing formulation: chitosan as a protecting agent

Background

Along with research on development of more efficient gene delivery systems, it is necessary to search on stabilization processes to extend their active life span. Chitosan is a nontoxic, biocompatible and available gene delivery carrier. The aim of this study was to assess the ability of this polymer to preserve transfection efficiency during spray-drying and a modified freeze-drying process in the presence of commonly used excipients.

Methods

Molecular weight of chitosan was reduced by a chemical reaction and achieved low molecular weight chitosan (LMWC) was complexed with pDNA. Obtained nanocomplex suspensions were diluted by solutions of lactose and leucine, and these formulations were spray dried or freeze dried using a modified technique. Size, polydispersity index, zeta potential, intensity of supercoiled DNA band on gel electrophoresis, and transfection efficiency of reconstituted nanocomplexes were compared with freshly prepared ones.

Results and conclusion

Size distribution profiles of both freeze dried, and 13 out of 16 spray-dried nanocomplexes remained identical to freshly prepared ones. LMWC protected up to 100% of supercoiled structure of pDNA in both processes, although DNA degradation was higher in spray-drying of the nanocomplexes prepared with low N/P ratios. Both techniques preserved transfection efficiency similarly even in lower N/P ratios, where supercoiled DNA content of spray dried formulations was lower than freeze-dried ones. Leucine did not show a significant effect on properties of the processed nanocomplexes. It can be concluded that LMWC can protect DNA structure and transfection efficiency in both processes even in the presence of leucine.     

Effect of Size and Serum Proteins on Transfection Efficiency of Poly ((2-dimethylamino)ethyl Methacrylate)-Plasmid Nanoparticles

Purpose. The aim of this study was to gain insight into the relation between the physical characteristics of particles formed by a plasmid and a synthetic cationic polymer (poly(2-dimethylamino)ethyl methacrylate, PDMAEMA) and their transfection efficiency. Methods. The PDMAEMA-plasmid particles were characterized by dynamic light scattering (size) and electrophoretic mobility measurements (charge). The transfection efficiency was evaluated in cell culture (COS-7 cells) using a pCMV-lacZ plasmid coding for -galactosidase as a reporter gene. Results. It was shown that the optimal transfection efficiency was found at a PDMAEMA-plasmid ratio of 3 (w/w), yielding stable and rather homogeneous particles (diameter 0.15 µm) with a narrow size distribution and a slightly positive charge. Particles prepared at lower weight ratios, showed a reduced transfection efficiency and were unstable in time as demonstrated by DLS measurements. Like other cationic polymers, PDMAEMA is slightly cytotoxic. This activity was partially masked by complexing the polymer with DNA. Interestingly, the transfection efficiency of the particles was not affected by the presence of serum proteins. Conclusions. PDMAEMA is an interesting vector for the design of in vivo and ex vivo gene transfection systems.     

Chitosan-DNA nanoparticles: effect on DNA integrity, bacterial transformation and transfection efficiency

While somatic gene therapy has the potential to treat many genetic disorders, recent clinical trials suggest that an efficient and safe delivery vehicle for successful gene therapy is lacking. The current study examines the influence of two different preparation (the solvent evaporation method and the complex coacervation method) methods on the encapsulation of a model plasmid with chitosan. The ability of different molecular weights of chitosan to form nanoparticles with a plasmid, and particulated polymers to stabilize a plasmid in a supercoiled form, were examined by agarose gel electrophoresis. Protection of encapsulated pDNA offered by these nanoparticles from nuclease attack was confirmed by assessing degradation in the presence of DNase I, and the transformation of the plasmids with incubated nanoparticles were examined by beta-galactosidase assay. Model pDNA existed as a mixture of both supercoiled (84.2%) and open circular (15.8%) forms. Our results demonstrated that supercoiled forms decreased while open circular forms and fragmented linear forms increased during the preparation of formulations. F1 formulation prepared by the complex coacervation method protected the supercoiled form of pDNA effectively. There weren't any significant changes in nanoparticle size and zeta potential values at pH 5.5 for a period of 3 months, but differences in particle sizes were observed after lyophilization with a cryoprotective agent. The efficiency of nanoparticles mediated transformation to Escherichia coli cells was significantly higher than naked DNA or poly-L-lysine (PLL)-DNA polycation complexes. The transfection studies were performed in COS-7 cells. A 3-fold increase in gene expression was produced by nanoparticles as compared to the same amount of naked plasmid DNA (pDNA). These observations suggest that formulations with high molecular weight (HMW) chitosan can be an effective non-viral method of gene vector in animal studies.     

N-Acyl-(α,γ Diaminobutyric Acid)n Hydrazide as an Efficient Gene Transfer Vector in Mammalian Cells in Culture

Purpose. This study investigates the structure/activity relationship of a series of N-acyl-peptides (lipopeptides) for the transfection of mammalian cells. Methods. Lipopeptides comprising 1 to 3 basic amino-acids and a single fatty acid chain were synthesized. Transfecting complexes between lipopeptide, plasmid DNA and dioleoyl phosphatidylethanolamine were prepared and applied on cells in culture. Transfection efficiency was evaluated by measuring -galactosidase activity 48 h post-transfection. Lipopeptide-DNA binding was also investigated by physical means and molecular modelling. Results. Besides the length of the fatty acid chain, the nature of the basic amino-acid and the C-terminal group were crucial parameters for high transfection efficiency. The N-acyl-(diaminobutyric acid)n derivatives were the most potent transfecting agents among those tested and induced a -galactosidase activity 2 to 20 times higher than the N-acyl-lysine, -ornithine or -diaminopropionic acid derivatives. Furthermore, a hydrazide C-terminal modification greatly enhanced transfection efficiency for all compounds tested. The reason why , -diaminobutyric acid hydrazide-based lipopeptides were the most potent in transfection is not fully understood but could be related to their high DNA binding. Conclusions. Poly- or oligo-diaminobutyric acid containing or not a hydrazide C-terminus could advantageously be used in peptide-based gene delivery systems.     

Preparation and Characterization of Poly (D,L-Lactide-Co-Glycolide) Microspheres for Controlled Release of Poly(L-Lysine) Complexed Plasmid DNA

Purpose. To produce and characterize controlled release formulations of plasmid DNA (pDNA) loaded in poly (D,L-lactide-co-glycolide) (PLGA) microspheres both in free form and as a complex with poly (L-lysine). Methods. Poly (L-lysine) (PLL) was used to form pDNA/PLL complexes with complexation ratio of 1:0.125 and 1:0.333 w/w to enhance the stability of pDNA during microsphere preparation and protect pDNA from nuclease attack. pDNA structure, particle size, zeta potential, drug loading, in vitro release properties, and protection from DNase I were studied. Results. The microspheres were found to be spherical with average particle size of 3.1-3.5 m. Drug loading of 0.6% was targeted. Incorporation efficiencies of 35.1% and 29.4-30.6% were obtained for pDNA and pDNA/PLL loaded microspheres respectively. Overall, pDNA release kinetics following the initial burst did not correlate with blank microsphere polymer degradation profile suggesting that pDNA release is convective diffusion controlled. The percentage of supercoiled pDNA in the pDNA and pDNA/PLL loaded microspheres was 16.6 % and 76.7-85.6% respectively. Unencapsulated pDNA and pDNA/PLL degraded completely within 30 minutes upon the addition of DNase I. Encapsulation of DNA/PLL in PLGA microspheres protected pDNA from enzymatic degradation. Conclusions. The results show that using a novel process, pDNA can be stabilized and encapsulated in PLGA microspheres to protect pDNA from enzymatic degradation.     

Terplex DNA Delivery System As a Gene Carrier

Purpose. To characterize the physical and biochemical properties of the DNA terplex delivery system, which has previously been shown to deliver and express pSV--gal plasmid efficiently in cultured smooth muscle cells (SMC) (1). Methods. Atomic force microscopy (AFM), zeta-potential measurement (ZP), gel electrophoresis (GE), circular dichroism (CD), fluorescence quenching and ¹H-NMR spectrometry were used. Results. AFM showed that the plasmid DNA of about 600 nm long in its extended state was condensed to the size of about 100 nm by terplex formation. The DNA condensing effect of the terplex system was as good as unmodified PLL, as shown by an ethidium bromide displacement assay. Zeta-potential measurement showed that the terplex system exerts a slightly positive surface charge (+2 mV) at a 1:1:1 weight ratio of DNA:LDL:stearyl-PLL, which showed the best transfection efficiency on SMC. GE indicated that electrophoretic mobility of the terplex system decreased with increasing amounts of stearyl-PLL, indicating that the surface charge of the terplex system became more positive as more stearyl-PLL was added. Results from CD showed that there was no significant changes in tertiary structure of plasmid DNA from the terplex formation. Presence of strong hydrophobic interaction between stearyl-PLL and LDL was confirmed by ¹H-NMR, where about a 30% decrease in -methylene peak of PLL backbone was observed when stearyl-PLL was mixed with LDL, but this phenomenon was not observed when unmodified PLL was used. Conclusions. Our results indicate that the plasmid DNA, when formulated with the stearyl-PLL and LDL, forms a stable and hydrophobicity / charge balanced terplex system of optimal size for efficient cellular uptake and the DNA is still intact after the terplex formation. This information is expected to be utilized for the development of much improved transfection vectors for in vivogene therapy.     

Cationic Nanomicelles for Delivery of Plasmids Encoding Interleukin-4 and Interleukin-10 for Prevention of Autoimmune Diabetes in Mice

Purpose  

To evaluate the in vivo transfection efficiency of N-acyl derivatives of low-molecular weight chitosan (LMWC) to deliver pVIVO2-mIL4-mIL10 plasmid encoding interleukin-4 (IL-4) and interleukin-10 (IL-10) in multiple, low-dose streptozotocin induced diabetic mouse model.     

In Vitro Gene Transfection in Human Glioma Cells Using a Novel and Less Cytotoxic Artificial Lipoprotein Delivery System

Purpose. To develop and evaluate a novel artificial lipoprotein delivery system for in vitro gene transfection in human glioma cells. Method. Nanoemulsion was formulated with similar lipid compositions present in natural lipoproteins. The oil phase of nanoemulsion was composed of triolein (70%), egg phosphatidylcholine (22.7%), lysophosphatidylcholine (2.3%), cholesterol oleate (3.0%), and cholesterol (2.0%). To replace the surface protein as in natural lipoprotein, poly-L-lysine was modified to add palmitoyl chains at a basic condition and was incorporated onto the nanoemulsion particles through hydrophobic interaction. A model plasmid DNA, pSV--Gal containing a reporter gene for -galactosidase was carried by the nanoemulsion/poly-L-lysine particles. The charge variation of so-formed complex was examined by agarose gel electrophoresis and zeta potential measurement. In vitro transfection was conducted on human SF-767 glioma cell line using this new system. After standard X-Gal staining, transfected cells were observed under light microscope. The effect of chloroquine on the transfection was examined and, finally, the cytotoxicity of this new system was evaluated in comparison with commercial Lipofectamine gene transfection system. Results. The plasmid DNA was effectively carried by this artificial lipoprotein delivery system and the reporter gene was expressed in the glioma cells. Transfection efficiency was significantly increased by the treatment of chloroquine, indicating that endocytosis possibly was the major cellular uptake pathway. Compared to Lipofectamine system, this new delivery system demonstrated similar transfection efficiency but a much lower cytotoxicity. In the experiment, the cell viability showed up to 75% using this system compared to only 24% using Lipofectamine system. Conclusion. A new artificial lipoprotein delivery system was developed for in vitro gene transfection in tumor cells. The new system showed similar transfection efficiency but a much lower cytotoxicity compared with commercial Lipofectamine system.     

Stability of Poly(l-Lysine)-Complexed Plasmid DNA During Mechanical Stress and DNase I Treatment

The aim of this study was to investigate the formation and stability of complexes between plasmid DNA (pDNA) and poly(l-lysine) (PLL). Formation of pDNA/PLL complexes with various ratios was determined by a fluorescence spectrophotometric method using fluorescamine. The effects of sonication, vortexing, and exposure to DNase I on the stability of free pDNA and pDNA/PLL complexes are discussed. A linear correlation between PLL added and PLL bound was obtained with overall reaction efficiency of 84.2–92.6%. Sonication degraded both free and PLL-complexed pDNA within 15 sec of vortexing. However, vortexing did not alter the stability of free and complexed pDNA. Dramatic increase in the protection of pDNA in pDNA/PLL complexes was observed in the DNase I digestion experiment; 68.1–89.0% of total pDNA in the pDNA/PLL complexes was protected from DNase I digestion compared to only 19.2% of total pDNA that remained undegraded after DNase I treatment of free pDNA. An increase in the PLL/pDNA ratio led to an increase in the protection of supercoiled pDNA; 15.5–38.2% of supercoiled pDNA in PLL/pDNA complexes was protected after DNase I treatment. The results show that complexation of pDNA with PLL can stabilize the supercoiled structure of pDNA for the development of biodegradable microspheres as a delivery system for pDNA. Stability of pDNA/PLL complex can be monitored by PicoGreen® dye and fluorescence densitometric assay methods.     

A Novel Non-Viral Vector for DNA Delivery Based on Low Molecular Weight,Branched Polyethylenimine: Effect of Molecular Weight on Transfection Efficiency and Cytotoxicity

Purpose. Low molecular weight branched polyethylenimine (LMW-PEI) was synthesized and studied as a DNA carrier for gene delivery with regard to physico-chemical properties, cytotoxicity, and transfection efficiency. Methods. The architecture of LMW-PEI, synthesized by acid catalyzed ring-opening polymerization of aziridine was characterized by size exclusion chromatography in combination with laser light scattering and ¹³C-NMR-spectroscopy. In vitro cytotoxic effects were quantified by LDH and MTT assay and visualized by transmission electron microscopy. The potential for transgene expression was monitored in ECV304 cells using luciferase driven by a SV40 promoter as reporter gene system. Results. LMW-PEI (Mw 11900 D) with a low degree of branching was synthesized as a DNA carrier for gene delivery. In contrast to high molecular weight polyethylenimines (HMW-PEI; Mw l616OOO D), the polymer described here showed a different degree of branching and was less cytotoxic in a broad range of concentrations. As demonstrated by transmission electron microscopy the LMW-PEI formed only small aggregates which were efficiently taken up by different cells in the presence of serum, most likely by an endocytic pathway. LMW-PEI yielded transfection efficiencies measured via expression of the reporter gene luciferase which were up to two orders of magnitude higher than those obtained with HMW-PEI. The reporter gene expression was concentration dependent, but in contrast to lipofection independent of serum addition. Conclusions. The LMW-PEI described here is a new, highly efficient, and non-cytotoxic vector with a favorable efficiency/toxicity profile for gene therapeutic applications.     

Randomly 50% N-acetylated low molecular weight chitosan as a novel renal targeting carrier

Selective targeting of drugs to kidneys may improve renal effectiveness and reduce extrarenal toxicity. Using fluorescence imaging, we found for the first time that randomly 50% N-acetylated low molecular weight chitosan (LMWC) selectively accumulated in the kidneys, especially in the renal tubules after i.v. injection in mice. To develop and evaluate the novel renal drug carrier, prednisolone, used as a model drug, was covalently coupled with various molecular weight LMWCs via a succinic acid spacer. The mean residence time (MRT) in plasma of prednisolone conjugates increased as the molecular weight increased. The conjugate with molecular weight 19 kD (conjugate-19k) displayed the highest accumulation rate in the kidneys, which was 14.06 ± 2.81% of the administered dose 15 min after i.v. injection. The total amount of the conjugate-19k in the kidneys was 13-fold higher than that of controlled prednisolone group. Both conjugate-19k and conjugate-31k had higher retention and about 10% of injected dose was still retained in the kidneys after 120 min. Additionally, MTT assay showed LMWCs were noncytotoxic towards L929 and NRK-52E cells. Conclusion can be drawn that the coupling of prednisolone to the proper molecular weight LMWC results in increased prednisolone concentration in the kidneys. Therefore, LMWC with a proper molecular weight can be applied as a promising carrier for renal targeting.     

Cross-linked Small Polyethylenimines: While Still Nontoxic,Deliver DNA Efficiently to Mammalian Cells <Emphasis Type="Italic">in Vitro</Emphasis> and <Emphasis Type="Italic">in Vivo</Emphasis>

No HeadingPurpose. Polyethylenimine (PEI) is among the most efficient nonviral gene delivery vectors. Its efficiency and cytotoxicity depend on molecular weight, with the 25-kDa PEI being most efficient but cytotoxic. Smaller PEIs are noncytotoxic but less efficient. Enhancement in gene delivery efficiency with minimal cytotoxicity by cross-linking of small PEIs via potentially biodegradable linkages was explored herein. The hypothesis was that cross-linking would raise the polycations effective molecular weight and hence the transfection efficiency, while biodegradable linkages would undergo the intracellular breakdown after DNA delivery and hence not lead to cytotoxicity. Toward this goal, we carried out cross-linking of branched 2-kDa PEI and its 1:1 (w/w) mixture with a linear 423-Da PEI via ester- and/or amide-bearing linkages; the in vitro and in vivo gene delivery efficiency, as well as toxicity to mammalian cells, of the resultant cross-linked polycations were investigated.Methods. The efficiency of the cross-linked PEIs in delivering in vitro a plasmid containing -galactosidase gene and their cytotoxicity were investigated in monkey kidney cells (COS-7). Dynamic light scattering was used to compare the relative DNA condensation efficiency of the unmodified and cross-linked PEIs. In vivo gene delivery efficiency was evaluated by intratracheal delivery in mice of the complexes of a luciferase-encoding plasmid and the PEIs and estimating the luciferase expression in the lungs.Results. Cross-linking boosted the gene delivery efficiency of the small PEIs by 40- to 550-fold in vitro; the efficiency of the most potent conjugates even exceeded by an order of magnitude that of the branched 25-kDa PEI. Effective condensation of DNA was evident from the fact that the mean diameter of the complexes of the cross-linked PEIs was some 300 nm with a narrow size distribution, while the complexes of the unmodified small PEIs exhibited a mean size of >700 nm with a very broad size distribution. At concentrations where the 25-kDa PEI resulted in >95% cell death, the conjugates afforded nearly full cell viability. The cross-linked PEIs were 17 to 80 times m ore efficient than the unmodified ones in vivo; furthermore, their efficiencies were up to twice that of the 25-kDa PEI.Conclusions. Cross-linking of small PEIs with judiciously designed amide- and ester-bearing linkers boosts their gene delivery efficiency both in vitro and in vivo without increasing the cytotoxicity. The high efficiency is dependent on the nature of the linkages and the PEIs used.     

Thiolated Chitosan/DNA Nanocomplexes Exhibit Enhanced and Sustained Gene Delivery

Purpose Thiolated chitosan appears to possess enhanced mucoadhesiveness and cell penetration properties, however, its potential in gene-drug delivery remains unknown. Herein, we report on a highly effective gene delivery system utilizing a 33-kDa thiol-modified chitosan derivative.Methods Thiolated chitosan was prepared by the reaction with thioglycolic acid. Nanocomplexes of unmodified chitosan or thiolated chitosan with plasmid DNA encoding green fluorescenct protein (GFP) were characterized for their size, zeta potential, their ability to bind and protect plasmid DNA from degradation. The transfection efficiency of thiolated chitosan and sustained gene expression were evaluated in various cell lines in vitro and in Balb/c mice in vivo.Results Thiolated chitosan–DNA nanocomplexes ranged in size from 75 to 120 nm in diameter and from +2.3 to 19.7 mV in zeta potential, depending on the weight ratio of chitosan to DNA. Thiolated chitosan, CSH360, exhibited effective physical stability and protection against DNase I digestion at a weight ratio ≥ 2.5:1. CSH360/DNA nanocomplexes induced significantly (P < 0.01) higher GFP expression in HEK293, MDCK and Hep-2 cell lines than unmodified chitosan. Nanocomplexes of disulphide-crosslinked CSH360/DNA showed a sustained DNA release and continuous expression in cultured cells lasting up to 60 h post transfection. Also, intranasal administration of crosslinked CSH360/DNA nanocomplexes to mice yielded gene expression that lasted for at least 14 days.Conclusions Thiolated chitosans condense pDNA to form nanocomplexes, which exhibit a significantly higher gene transfer potential and sustained gene expression upon crosslinking, indicating their great potential for gene therapy and tissue engineering.     

Synergistic Effect of Formulated Plasmid and Needle-Free Injection for Genetic Vaccines

Purpose. A plasmid-based gene expression system was complexed with protective, interactive, and non-condensing (PINC) polymer system and administered with Medi-Jector, a needle-free injection device (NFID), to achieve high and sustained levels of antigen-specific antibodies in blood circulation. Methods. Human growth hormone (hGH) or bacterial -galactosidase gene expression plasmids driven by a cytomegalovirus (CMV) promoter were formulated in saline or complexed with a PINC polymer, polyvinylpyrrolidone (PVP), and intramuscularly or subcutaneously administered into dogs and pigs using a 22-gauge needle or a NFID. The hGH-specific IgG titers in serum were measured by an ELISA. -galactosidase expression was measured in injected muscles by an enzymatic assay or immunohistochemistry. The effect of NFID on DNA stability and topology was assessed by gel electrophoresis. Results. Intramuscular (i.m.) or subcutaneous (s.c.) injection of a hGH expression plasmid pCMV-hGH (0.05-0.5 mg/kg) in dogs and pigs elicited antigen-specific IgG antibody titers to expressed hGH. With both routes of injection, pDNA delivery by a NFID was superior to pDNA injection by needle. The magnitude of hGH-specific IgG titers with NFID was 15–20-fold higher than needle injection when pDNA was complexed with PVP, and only 3–4-fold higher with pDNA in saline. The transfection efficiency in the injected muscle, as measured by -galaclosidase expression, following i.m. injection of pCMV--galaclosidase/PVP, was not significantly different between needle and NFID-injected groups. Conclusions. These data demonstrate that the combination of pDNA/ PVP complexes and a NFID act synergistically to achieve high and sustained levels of antigen-specific IgG response to expressed antigen. This gene delivery approach may offer advantage over needle injection of naked DNA for the development of genetic vaccines.     

The Lower-Generation Polypropylenimine Dendrimers Are Effective Gene-Transfer Agents

Objective. To evaluate polypropylenimine dendrimers (generations 1-5: DAB 4, DAB 8, DAB 16, DAB 32, and DAB 64) as gene delivery systems. Methods. DNA binding was evaluated by measuring the reduced fluorescence of ethidium bromide, and molecular modelling of dendrimer-DNA complexes also was performed. Cell cytotoxicity was evaluated against the A431 cell line using the MTT assay. In vitro transfection was evaluated against the A431 cell line using the -galactosidase reporter gene and N-[1-(2,3-dioleoyloxy)propyl]-N,N,N-trimethylammonium methylsulphate (DOTAP) served as a positive control. Results. Molecular modeling and experimental data revealed that DNA binding increased with dendrimer generation. Cell cytotoxicity was largely generation dependent, and cytotoxicity followed the trend DAB 64 > DAB 32 > DAB 16 > DOTAP > DAB 4 > DAB 8, whereas transfection efficacy followed the trend DAB 8 = DOTAP = DAB 16 > DAB 4 > DAB 32 = DAB 64. Conclusion. The generation 2 polypropylenimine dendrimer combines a sufficient level of DNA binding with a low level of cell cytoxicity to give it optimum in vitro gene transfer activity.     

中心组合设计法优化载基因壳聚糖纳米粒的最佳转染制备区域

目的：采用中心组合设计法优化载基因壳聚糖纳米粒的最佳转染制备区域。方法采用复凝聚法制备载质粒基因的壳聚糖纳米粒,选择壳聚糖浓度和质粒基因浓度作为实验考察因素,应用两因素五水平中心组合设计优化最佳转染制备区域,优化指标选择平均粒径和基因转染率。通过透射电镜观察纳米粒的形态;通过动态光散射和电泳光散射技术分别测量纳米粒的粒径和Zeta电位;通过凝胶电泳分析考察质粒在纳米粒制备过程中的稳定性;通过倒置荧光显微镜观察质粒基因在细胞内的表达;通过流式细胞技术测定纳米粒的转染效率。结果成功优化了载基因壳聚糖纳米粒的最佳转染制备区域。优选条件下制备的纳米粒大多呈球形,纳米粒平均粒径为217．6 nm,粒径多分散系数为0．241,表明粒径分布较窄。纳米粒zeta电位为＋22．4 mV,表明纳米粒表面带有正电荷,可以增加纳米粒混悬液的稳定性。凝胶电泳分析结果表明质粒基因在纳米粒制备过程中没有遭到破坏。纳米粒的细胞转染效率比较高,能够高效地将绿色荧光蛋白质粒基因递送到细胞内,并且基因表达产生绿色荧光蛋白。结论本研究建立的数学模型具有良好的预测性。在优化的制备区域内制备的载基因壳聚糖纳米粒的转染性能比较理想。