Cationic Liposomes Containing Disulfide Bonds in Delivery of Plasmid DNA

Abstract

Cationic liposomes are non-viral gene transfer vectors for in vitro and in vivo experiments. In the present studies, we investigated whether a disulfide linkage in a cationic lipid was reducible by cell lysate resulting in the release of plasmid DNA and enhanced gene transfection. We also investigated if the differences in transgene production were from differences in total amount of cellular associated plasmid DNA. We systematically compared the gene transfection of disulfide bond containing-cationic lipid, 1', 2'-dioleoyl-sn-glycero-3'-succinyl-2-hydroxyethyl disulfide ornithine conjugate (DOGSDSO), its non-disulfide-containing analog, 1', 2'-dioleyl-sn-glycero-3'-succinyl-1, 6-hexanediol ornithine conjugate (DOGSHDO), 1, 2-dioleoyl-3-trimethylammonium-propane (DOTAP). Two transgene reporter systems (i.e., luciferase and green fluorescent protein (GFP)) were used to address transgene transgene expression and transgene efficiency. Experiments with the luciferase expression plasmid resulted in transgene activity up to 11 times greater transgene production for the disulfide containing lipid in at least two different cell lines, COS 1 and CHO cells. When transgene expression was determined by GFP activity, DOGSDSO liposomes were four times greater than the non-disulfide lipid or positive control (DOTAP) liposomes. By quantifying nucleic acid uptake by flow cytometry it was also demonstrated that increase expression was not solely from an increase in cellular plasmid DNA accumulation. These results demonstrate that cationic lipids containing a disulfide linkage are a promising method for gene transfer.     

In Vivo Gene Transfer to the Mouse Nasal Cavity Mucosa Using a Stable Cationic Lipid Emulsion

We evaluate a new cationic emulsion as a mucosal gene carrier and elucidate the relationship between the transfection efficiency and the stability of the carrier/DNA complex. A cationic lipid emulsion was formulated with soybean oil and 1,2-dioleoyl-sn-glycero-3-trimethylammonium-propane (DOTAP) as major components and was used to transfer genes to the epithelial cells of the mouse nasal cavity via intranasal instillation. Correlation between the transfection efficiency and the stability of the carrier/DNA complex was investigated by measuring the carrier size changes and by observing the degree of DNA protection against DNase I digestion in the presence of heparin. The cationic emulsion showed at least 3 times better transfection activity than the liposomal carriers in nasal mucosae. The cationic emulsion was stable in the presence of heparin whereas the liposomal carriers became very unstable. Unlike DNA in liposome/DNA complexes, DNA in the emulsion/DNA complex was resistant to heparin exchange and DNase I digestion. The cationic emulsion was more effective in delivering DNA to nasal mucosae than commercially available liposomal carriers. The transfection activities of the lipid carriers in nasal cavity mucosae are in agreement with the stability of the lipid carriers and their complexes with DNA.     

FACTORS INFLUENCING THE EFFICIENCY OF LIPOPLEXES MEDIATED GENE TRANSFER IN LUNG AFTER INTRAVENOUS ADMINISTRATION*

The objectives of this study were to test the influence of different parameters on the in vivo cationic lipid mediated gene transfer in lung after intravenous administration. Luciferase activity was evaluated in lung tissue 24 hours after intravenous administration of different types of lipoplexes. These included lipoplexes prepared using cationic phosphonolipids or DOTAP and various amounts of plasmid DNA. Using two different plasmids we tested the influence of plasmid size on transfection efficiency in vivo. In a last series of experiments, lipoplexes were prepared using different excipients (water, NaCl or 5% glucose solution) and three injection volumes were tested. We demonstrate that chemical structure modifications such as cation substitution and increment of the aliphatic chain length significantly improve transfection efficiency. High luciferase levels are obtained by increasing lipid to DNA charge ratio and plasmid DNA dose and decreasing plasmid size. Lipoplexes prepared in physiological NaCl solution and injected using a volume of 800μl are significantly the most effective.

Cationic lipid mediated gene transfer in lung tissue after intravenous administration is influenced by factors including cationic lipid chemical structure, lipid to DNA ratio and plasmid dose. Nevertheless, plasmid size, injection volume and the excipient, used for the lipoplexes preparation, are also important factors and must be considered for an optimization of in vivo gene delivery using intravenous administration.     

The counterion influence on cationic lipid-mediated transfection of plasmid DNA

A panel of DOTAP analogs was prepared by altering the anionic counterion that accompanies the trimethylammonium polar domain. The transfection of plasmid DNA into NIH3T3 cells and mouse lung was examined using the counterion analogs. The in vitro transfection activity decreased as follows: DOTAP · bisulfate > trifluoromethanesulfonate ∼ iodide ∼ bromide > dihydrogenphosphate ∼ chloride ∼ acetate > sulfate. A similar activity trend was observed in vivo.     

A pH-sensitive polymer that enhances cationic lipid-mediated gene transfer.

The efficient release of nonviral gene carriers from endosomes is an important step for the successful delivery of DNA into the cell nucleus. A synthetic pH-sensitive anionic polymer, poly(propylacrylic acid) (PPAA), was designed to aid in endosomal escape of nonviral vectors and improve the transfection efficiencies with these vectors. Transfection of NIH3T3 fibroblasts with ternary physical mixtures of the cationic lipid DOTAP, pCMVbeta plasmid DNA, and PPAA showed marked enhancement of both gene expression levels and fraction of cells transfected compared to binary control mixtures of DOTAP and DNA. PPAA also significantly improved the serum-stability of DOTAP/DNA vectors. The DOTAP/DNA/PPAA vectors maintained high levels of transfection in media containing up to 50% serum. The striking enhancement of transfection efficiency with cationic lipid/DNA/PPAA mixtures, along with the enhanced serum-stability, suggests that PPAA may provide significant improvements for the in vivo intracellular delivery of drugs such as DNA, oligonucleotides, proteins, and peptides.     

Interplay in lipoplexes between type of pDNA promoter and lipid composition determines transfection efficiency of human growth hormone in NIH3T3 cells in culture.

This study was aimed to investigate if and to what extent there is an interplay between lipoplex physicochemical properties and plasmid promoter type affecting transfection efficiency in vitro. To reduce the number of variables only one cell type (NIH3T3 cells), one gene (human growth hormone), one cationic lipid (DOTAP) in a plasmid >85% in supercoiled form, and the same medium conditions were used. The variables of the physicochemical properties included presence and type of helper lipid (DOPE, DOPC, or cholesterol, all in 1:1 mole ratio with DOTAP), size and lamellarity of the liposomes used for lipoplex preparation (large unilamellar vesicles, LUV, versus multilamellar vesicles, MLV), and DNA(-)/cationic lipid(+) charge ratio, all containing the same human growth hormone but differing in their promoter enhancer region. Two of the promoters were of viral origin: (a) SV40 promoter (simian virus early promoter) and (b) CMV promoter (cytomegalovirus early promoter); two were of mammalian cell origin: (c) PABP promoter (human poly(A)-binding protein promoter) and (d) S16 promoter (mouse ribosomal protein (rp) S16 promoter). Transfection studies showed that, irrespective of promoter type, large (> or =500 nm) MLV were superior to approximately 100 nm LUV; the extent of superiority was dependent on liposome lipid composition (larger for 100% DOTAP and DOTAP/DOPE than for DOTAP/DOPC and DOTAP/cholesterol). The optimal DNA(-)/DOTAP(+) charge ratio for all types of lipoplexes used was 0.2 or 0.5 (namely, when the lipoplexes were positively charged). Scoring the six best lipoplex formulations (out of 128 studied) revealed the following order: pCMV (DOTAP/DOPE) > pSV (DOTAP/DOPE)=pCMV(DOTAP/cholesterol)=pS16 (100% DOTAP)=pS16 DOTAP/DOPE > pCMV (DOTAP/DOPC). The lack of trivial consistency in the transfection efficiency score, the pattern of transfection efficiency, and statistical analysis of the data suggest that there is cross-talk between promoter type and lipoplex lipid composition, which may be related to the way the promoter is associated with the lipids.     

Lamellarity of cationic liposomes and mode of preparation of lipoplexes affect transfection efficiency.

Transfection of NIH-3T3 cells by a human growth hormone expression vector complexed with liposomes composed of N-(1-(2, 3-dioleoyloxy)propyl)-N,N,N-trimethylammonium chloride (DOTAP) with or without helper lipids was studied. The transfection efficiency was dependent on the lamellarity of the liposomes used to prepare the lipoplexes. Multilamellar vesicles (MLV) were more effective than large unilamellar vesicles (LUV) of approximately 100 nm, irrespective of lipid composition. The optimal DNA/DOTAP mole ratio for transfection was 相似文献   

Physicochemical characterization and purification of cationic lipoplexes.

Cationic lipid-nucleic acid complexes (lipoplexes) consisting of dioleoyltrimethylammoniumpropane (DOTAP) liposomes and plasmid DNA were prepared at various charge ratios (cationic group to nucleotide phosphate), and the excess component was separated from the lipoplex. We measured the stoichiometry of the lipoplex, noted its colloidal properties, and observed its morphology and structure by electron microscopy. The colloidal properties of the lipoplexes were principally determined by the cationic lipid/DNA charge ratio and were independent of the lipid composition. In lipoplexes, the lipid membranes as observed in freeze-fracture electron microscopy were deformed into high-radius-of-curvature features whose characteristics depended on the lipid composition. Lipoplexes prepared at a threefold or greater excess of either DOTAP or DNA could be resolved into complexes with a defined stoichiometry and the excess component by sedimentation to equilibrium on sucrose gradients. The separated, positively charged complex retained high transfection activity and had reduced toxicity. The negatively charged lipoplex showed increased transfection activity compared to the starting mixture. In cryoelectron micrographs the positively charged complex was spherical and contained a condensed but indistinct interior structure. In contrast, the separated negatively charged lipoplexes had a prominent internal 5.9 +/- 0.1-nm periodic feature with material projecting as spikes from the spherical structure into the solution. It is likely that these two lipoplexes represent structures with different lipid and DNA packing.     

Characterization of cationic lipid DNA transfection complexes differing in susceptability to serum inhibition

Background

Cationic lipid DNA complexes based on DOTAP (1,2-dioleoyl-3-(trimethyammonium) propane) and mixtures of DOTAP and cholesterol (DC) have been previously optimized for transfection efficiency in the absence of serum and used as a non-viral gene delivery system. To determine whether DOTAP and DC lipid DNA complexes could be obtained with increased transfection effciency in the presence of high serum concentrations, the composition of the complexes was varied systematically and a total of 162 different complexes were analyzed for transfection efficiency in the presence and absence of high serum concentrations.

Results

Increasing the ratio of DOTAP or DC to DNA led to a dose dependent enhancement of transfection efficiency in the presence of high serum concentrations up to a ratio of approximately 128 nmol lipid/μg DNA. Transfection efficiency could be further increased for all ratios of DOTAP and DC to DNA by addition of the DNA condensing agent protamine sulfate (PS). For DOTAP DNA complexes with ratios of ≤ 32 nmol/μg DNA, peak transfection efficiencies were obtained with 4 μg PS/μg DNA. In contrast, increasing the amount of PS of DC complexes above 0.5 μg PS /μg DNA did not lead to significant further increases in transfection efficiency in the presence of high serum concentrations. Four complexes, which had a similar high transfection efficiency in cell culture in the presence of low serum concentrations but which differed largely in the lipid to DNA ratio and the amount of PS were selected for further analysis. Intravenous injection of the selected complexes led to 22-fold differences in transduction efficiency, which correlated with transfection efficiency in the presence of high serum concentrations. The complex with the highest transfection efficiency in vivo consisted of 64 nmol DC/ 16 μg PS/ μg DNA. Physical analysis revealed a predicted size of 440 nm and the highest zeta potential of the complexes analyzed.

Conclusions

Optimization of cationic lipid DNA complexes for transfection efficiency in the presence of high concentrations of serum led to the identification of a DC complex with high transduction efficiency in mice. This complex differs from previously described ones by higher lipid to DNA and PS to DNA ratios. The stability of this complex in the presence of high concentrations of serum and its high transduction efficiency in mice suggests that it is a promising candidate vehicle for in vivo gene delivery.     

DNA pre-condensation with an amino acid-based cationic amphiphile. A viable approach for liposome-based gene delivery

A study related to the development and characterization of a new gene delivery system was performed. The approach consists in both the pre-condensation of plasmid DNA with an arginine-based cationic surfactant, arginine–N-lauroyl amide dihydrochloride (ALA), which was found not to be toxic, and the incorporation of the blood protein transferrin (Tf) into the formulations.Two cationic liposome formulations were used, one composed of a mixture of dioleoyl trimethylammoniopropane and cholesterol (DOTAP:Chol) and the other a pH sensitive formulation constituted of DOTAP, Chol, Dioleoyl phosphatidylethanolamine (DOPE) and cholesteryl hemisuccinate (CHEMS).Particles with different ALA/DNA and cationic lipid/DNA charge ratios were produced and a physicochemical characterization of the systems developed was performed. DNA conformational changes in the presence of ALA were studied by Circular Dichroism (CD) and the ALA binding to DNA was followed by surface tension measurements. Insight into the structure and morphology of the various ALA-complexes (complexes composed of ALA, DNA, Tf and liposomes) was obtained by cryogenic-Transmission Electron Microscopy (cryo-TEM) and the sizes of the ALA-complexes were determined through Photon Correlation Spectroscopy (PCS). We found that the transfection capacity of these systems is directly related with the presence of ALA and the lipidic composition. Complexes based on the pH sensitive liposome formulation present better transfection profiles. The correlation between the inner structure, density and size of the ALA-complexes and their biological activity is discussed. Overall, we demonstrate that the presence of ALA improves the transfection efficiency when conjugated with cationic liposome systems.     

Characterization of the interplay between the main factors contributing to lipoplex-mediated transfection in cell cultures

Transfection efficiency of lipoplex-mediated gene delivery is multifactorial. However, the mode of interaction between the factors which affect transfection is not fully understood. To help fill this deficiency we evaluated the effect of the interplay between several variables that affect transfection efficiency in cell cultures. For this, we applied the Analysis of Variance Model with Fixed Effects and Repeated Measures to assess the data. The variables studied include: two different genes, Luc, and human growth hormone (hGH), in three different plasmids (two of which contain the luciferase (Luc) gene, but different promoter-enhancer regions (CMV and H19) and one plasmid coding hGH with a S16 promoter); three topoisoforms of pDNA (supercoiled (SC), open circular (OC), and closed circular (CC)); three cationic lipid compositions, all based on the monocationic lipid DOTAP (100% DOTAP, DOTAP/DOPE 1 : 1, and DOTAP/cholesterol 1 : 1, all ratios are mole ratios); two DNA-/L+ charge ratios (0.2 and 0.5); and two cell lines (NIH 3T3 and MBT-2). Our statistical analysis confirmed that the cell type, the gene used for transfection, the promoter type, the type of helper lipid, and DNA-/DOTAP+ charge ratio, all affect transfection efficiency in a statistically significant manner. The most efficient lipoplex formulation in both cell lines was that based on DOTAP (without helper lipid), having CC plasmid DNA. We suggest that for obtaining the most transfection-efficient lipoplex one should select the best topoisoform of pDNA for each particular cell type, and complex it with cationic liposomes having optimal lipid composition.     

DNA pre-condensation with an amino acid-based cationic amphiphile. A viable approach for liposome-based gene delivery

A study related to the development and characterization of a new gene delivery system was performed. The approach consists in both the pre-condensation of plasmid DNA with an arginine-based cationic surfactant, arginine-N-lauroyl amide dihydrochloride (ALA), which was found not to be toxic, and the incorporation of the blood protein transferrin (Tf) into the formulations.Two cationic liposome formulations were used, one composed of a mixture of dioleoyl trimethylammoniopropane and cholesterol (DOTAP:Chol) and the other a pH sensitive formulation constituted of DOTAP, Chol, Dioleoyl phosphatidylethanolamine (DOPE) and cholesteryl hemisuccinate (CHEMS).Particles with different ALA/DNA and cationic lipid/DNA charge ratios were produced and a physicochemical characterization of the systems developed was performed. DNA conformational changes in the presence of ALA were studied by Circular Dichroism (CD) and the ALA binding to DNA was followed by surface tension measurements. Insight into the structure and morphology of the various ALA-complexes (complexes composed of ALA, DNA, Tf and liposomes) was obtained by cryogenic-Transmission Electron Microscopy (cryo-TEM) and the sizes of the ALA-complexes were determined through Photon Correlation Spectroscopy (PCS). We found that the transfection capacity of these systems is directly related with the presence of ALA and the lipidic composition. Complexes based on the pH sensitive liposome formulation present better transfection profiles. The correlation between the inner structure, density and size of the ALA-complexes and their biological activity is discussed. Overall, we demonstrate that the presence of ALA improves the transfection efficiency when conjugated with cationic liposome systems.     

Biophysical properties and supramolecular structure of self-assembled liposome/ε-peptide/DNA nanoparticles: correlation with gene delivery

Using solid-phase synthesis, lysine can be oligomerized by a reaction of the peptide carboxylate with the ε-amino group to produce nontoxic, biodegradable cationic peptides, ε-oligo(L-lysines). Here α-substituted derivatives of such ε-oligo(L-lysines) containing arginine and histidine in the side chain were tested as vectors for in vitro gene delivery. Combination of ε-oligolysines with the cationic lipid DOTAP and plasmid DNA resulted in transfection efficiency exceeding that of DOTAP alone, without significant increase in cytotoxicity. Synchrotron small-angle X-ray scattering studies revealed self-assembly of the DOTAP, ε-oligolysines, and DNA to ordered lamellar complexes. High transfection efficiency of the nanoparticles correlates with increase in zeta potential above +20 mV and requires particle size to be below 500 nm. The synergistic effect of branched ε-oligolysines and DOTAP in gene delivery can be explained by the increase in surface charge and by the supramolecular structure of the DOTAP/ε-oligolysine/DNA nanoparticles.     

trans-2-Aminocyclohexanol-based amphiphiles as highly efficient helper lipids for gene delivery by lipoplexes

Lipidic amphiphiles equipped with the trans-2-aminocyclohexanol (TACH) moiety are promising pH-sensitive conformational switches (“flipids”) that can trigger a lipid bilayer perturbation in response to increased acidity. Because pH-sensitivity was shown to improve the efficiency of several gene delivery systems, we expected that such flipids could significantly enhance the gene transfection by lipoplexes. Thus a series of novel lipids with various TACH-based head groups and hydrocarbon tails were designed, prepared and incorporated into lipoplexes that contain the cationic lipid 1,2-dioleoyl-3-trimethylammonio-propane (DOTAP) and plasmid DNA encoding a luciferase gene. B16F1 and HeLa cells were transfected with such lipoplexes in both serum-free and serum-containing media. The lipoplexes consisting of TACH-lipids exhibited up to two orders of magnitude better transfection efficiency and yet similar toxicity compared to the ones with the conventional helper lipids 1,2-dioleoyl-sn-glycero-3-phosphoethanolamine (DOPE) or cholesterol. Thus, the TACH-lipids can be used as novel helper lipids for efficient gene transfection with low cytotoxicity.     

Mechanistic evaluation of the transfection barriers involved in lipid-mediated gene delivery: Interplay between nanostructure and composition

Here we present a quantitative mechanism-based investigation aimed at comparing the cell uptake, intracellular trafficking, endosomal escape and final fate of lipoplexes and lipid–protamine/deoxyribonucleic acid (DNA) (LPD) nanoparticles (NPs) in living Chinese hamster ovary (CHO) cells. As a model, two lipid formulations were used for comparison. The first formulation is made of the cationic lipid 1,2-dioleoyl-3-trimethylammonium-propane (DOTAP) and the zwitterionic lipid dioleoylphosphocholine (DOPC), while the second mixture is made of the cationic 3β-[N-(N,N-dimethylaminoethane)-carbamoyl] cholesterol (DC-Chol) and the zwitterionic helper lipid dioleoylphosphatidylethanolamine (DOPE). Our findings indicate that lipoplexes are efficiently taken up through fluid-phase macropinocytosis, while a less efficient uptake of LPD NPs occurs through a combination of both macropinocytosis and clathrin-dependent pathways. Inside the cell, both lipoplexes and LPD NPs are actively transported towards the cell nucleus, as quantitatively addressed by spatio-temporal image correlation spectroscopy (STICS). For each lipid formulation, LPD NPs escape from endosomes more efficiently than lipoplexes. When cells were treated with DOTAP–DOPC-containing systems the majority of the DNA was trapped in the lysosome compartment, suggesting that extensive lysosomal degradation was the rate-limiting factors in DOTAP–DOPC-mediated transfection. On the other side, escape from endosomes is large for DC-Chol–DOPE-containing systems most likely due to DOPE and cholesterol-like molecules, which are able to destabilize the endosomal membrane. The lipid-dependent and structure-dependent enhancement of transfection activity suggests that DNA is delivered to the nucleus synergistically: the process requires both the membrane-fusogenic activity of the nanocarrier envelope and the employment of lipid species with intrinsic endosomal rupture ability.     

Efficient lipid-mediated transfection of DNA into primary rat hepatocytes

Cationic lipids are an effective means for transfecting nucleic acids into a variety of cell types. Very few of these lipids, however, have been reported to be effective with primary cells. We report on the efficacy of several commercially available cationic lipid reagents to transfect plasmid DNA into primary rat hepatocytes in culture. The reagents tested in this study include TransfectAce, LipofectAmine, Lipofectin, N-[1-(2,3-dioleyloxy)propyl]-n,n,n-trimethylammoniumchloride (DOTMA), (N-[1-(2,3-dioleoyloxy)propyl]-N,N,N-trimethyl-ammonium methylsulfate (DOTAP), and cetyltrimethyl-ammonium bromide/dioleoylphosphatidylethanol-amine (CTAB/DOPE). Electron micrographic (EM) studies indicate that similar size Lipofectin and DOTAP vesicles contain DNA-like material internally and that these vesicles attach to the cell membrane. DOTAP vesicles are multilamellar, appear as clusters, and have a high DNA-to-lipid ratio. Lipofectin vesicles appear to attach to the cell surface as individual vesicles. The EM observations are consistent with current theories on the mechanism of transfection by cationic lipids. While Lipofectin has proven to be effective in transfection studies of primary cells in culture, we have found DOTAP to be a viable alternative. DOTAP yields transfection rates in hepatocytes comparable to DOTMA and Lipofectin, however, at lower concentrations of reagent and at considerably less cost. Optimal conditions for transfecting 5 μg of plasmid DNA with DOTAP were achieved by utilizing multilamellar (vortexed) vesicles at a concentration of 15 μg DOTAP per 2 ml media in 60-mm plates for 2 h transfection time. In this study, DOTAP has proven to be economical, easy to prepare, and very effective in transfecting DNA into primary rat hepatocytes.     

Airway gene transfer using cationic emulsion as a mucosal gene carrier

BACKGROUND: Delivery of genes to airway mucosa would be a very valuable method for gene therapy and vaccination. However, there have been few reports on suitable gene delivery systems for administration. In this study, we use a cationic emulsion system, which is physically stable and facilitates the transfer of genes in the presence of up to 90% serum, as a mucosal gene carrier. METHODS AND RESULTS: Cationic lipid emulsion was formulated with squalene and 1,2-dioleoyl-sn-glycero-3-trimethylammoniumpropane (DOTAP) as major components. Emulsions formed stable complexes with DNA and protected and transferred DNA to target cells against DNase I digestion in the presence of mucosal destabilizers such as heparin sulfate (a polysaccharide of the glycosaminoglycan family in mucosa) and Newfectan (a natural lung extract of bovine) in an in vitro system. In contrast, commercial liposomes and counter liposomes, made with an identical lipid composition of emulsions, failed. After in vivo intranasal instillation, the cationic emulsion showed at least 200 times better transfection activity than the liposomal carriers in both nasal tissue and lung. CONCLUSIONS: These findings show that cationic emulsions can mediate gene transfection into airway epithelium, making it a good choice for transferring therapeutic genes and for genetic vaccination against an pathogenic infection via an airway route.     

A simple but effective cancer vaccine consisting of an antigen and a cationic lipid

Developing a cancer vaccine with a potent adjuvant, which is safe for human use, remains to be an unmet need. In this study, we developed a simple, safe, yet efficient, peptide-based therapeutic cancer vaccine, DOTAP/E7 complex, which comprises only two molecules: a DOTAP cationic lipid and a peptide antigen derived from E7 oncoprotein of human papillomavirus (HPV) type 16. The anti-cancer activity of DOTAP/E7 against existing HPV positive TC-1 tumor was compared to that of our previous LPD/E7 formulation, which contains bacterial DNA CpG motifs. Tumor-bearing mice showed significant tumor inhibition following a single vaccination of either formulation at the optimal lipid dose, suggesting that DOTAP liposome alone can provide a potent adjuvant activity without plasmid DNA. E7 peptide formulated with DOTAP induced migration of activated dendritic cells (DC) to the draining lymph node (DLN) and efficiently generated functional antigen-specific CD8⁺ T lymphocyte responses. Accumulation of CD8⁺ tumor infiltrating T cells and apoptosis at tumor sites were observed after treatment with DOTAP/E7 complexes, which was also associated with a decreased amount of CD25⁺Foxp3⁺ regulatory T cells in treated animals. Reactive oxygen species (ROS) induced by DOTAP cationic lipid in DLN revealed a plausible mechanism of the initial interaction between DC and DOTAP. An adequate amount of ROS generation was apparently required for the initiation of the vaccine mechanism; however, an overdose of DOTAP induced massive ROS production and apoptosis of DC in DLN, which led to diminished anti-cancer immunity. Overall, these results indicate that cationic lipid DOTAP alone serves as an efficient vaccine adjuvant for the induction of a therapeutic, antigen-specific anti-cancer activity.     

Protamine Sulfate Provides Enhanced and Reproducible Intravenous Gene Transfer by Cationic Liposome/DNA Complex

Abstract

A novel lipid/polycation/DNA (LPD) formulation has been developed for in vivo gene transfer. It involves the condensation of plasmid DNA with protamine sulfate, a cationic polypeptide, followed by the addition of DOTAP cationic liposomes. Compared with DOTAP/DNA complex, LPD offers greater protection of plasmid DNA against enzymatic digestion and gives consistently higher gene expression in mice via tail vein injection. The in vivo efficiency of LPD was dependent upon charge ratio and was also affected by the lipid used. Increasing the amount of DNA delivered induced an increase in gene expression. The optimal dose was approximately 50 μg per mouse, at which concentration approximately 10 ng luciferase protein per mg extracted tissue protein could be detected in the lung. Gene expression in the lung was detected as early as 1 h after injection, peaked at 6 h, and declined thereafter. Using LacZ as a reporter gene, it was shown that endothelial cells were the primary locus of transgene expression in both lung and spleen. No sign of inflammation in these organs was noticed. Since protamine sulfate has been proven to be non-toxic and only weakly immunogenic in humans, this novel vector may be useful for the clinical use of gene therapy.     

Transfection using synthetic peptides: comparison of three DNA-compacting peptides and effect of centrifugation

Positively charged peptides have been shown to allow efficient transfection in vitro, especially when mixed with lipids. We have compared the ability of three positively charged peptides both to compact DNA and to increase the transfection efficiency of the cationic lipid DOTAP. The peptides are: a polymer of 17 lysines (pK17), YKAWK8WK (peptide K8) and SPKRSPKRSPKR (peptide P2). Peptides pK17 and K8 compact DNA efficiently in a gel retardation assay and protect DNA efficiently against DNase I degradation. Peptide P2, on the other hand, interacts weakly with DNA and provides poor protection. In order to compare their transfection efficiency, the three peptides were mixed with DNA (plasmid pEGFP-N1) at different charge ratios (+/-) and DOTAP (at a charge ratio of 2). The transfection efficiency was measured by FACS analysis at different times post-transfection. With NIH-3T3 cells, peptide P2 provides the highest transfection efficiency (about 40%), when compared with peptides pK17 (29%) and K8 (31%) and DOTAP alone (21%) under optimal conditions. Finally, we showed that centrifugation of the complexes onto the cells increased the transfection efficiency by a factor 1.5 to 2 with the various cell lines tested (ECV, primary human keratinocyte, CFT-2, NT-1).