Assembly of Plasmid DNA into Liposomes After Condensation by Cationic Lipid in Anionic Detergent Solution

A novel strategy to prepare negatively charged and small DNA-containing liposomes after condensation of plasmid DNA by a cationic lipid in deoxycholate micelle environment is described. The average diameter of resulting complexes was 62±8 nm. DNA-containing liposomes were then prepared by dialysis. The shape of the resulting liposomes was spherical. The average diameter and the surface charge of the liposomes were 86±6 nm and −24±3 mV, respectively. The plasmid DNA inside liposomes remained in a supercoiled form after incubation with DNase.     

Improved Encapsulation of DNA in pH-Sensitive Liposomes for Transfection

Abstract

A simple method has been developed to prepare liposomes containing large amounts of DNA. The procedure consisted of three cycles of freeze-thawing a mixture of sonicated liposomes and DNA. The encapsulation efficiency depended on the size of DNA. For a small plasmid (2.7 kb), approximately 40% of input DNA was entrapped with an efficiency of 16 μgDNA/μmol lipid. For larger plasmids, the encapsulation efficiency decreased considerably. Transfection of cultured mouse L929 cells mediated by the DNA-containing liposomes was assayed with a plasmid containing the E. coli chloramphenicol acetyl transferase gene. The transfection activity of the liposome was primarily determined by its pH sensitivity. Acid-sensitive liposomes transfected cells efficiently, whereas pH-insensitive liposomes were much less active. The level of the expression of the exogenous gene in the treated cells could be further modulated by protein kinase C (PKC) activators that were incorporated into the liposomal membrane as a minor lipid component. Transfection conditions were optimized with respect to DNA, lipid, and PKC activator concentrations. The results of the current study may help the use of liposomal delivery system for applications in gene therapy.     

Entrapment of high-molecular-mass DNA molecules in liposomes for the genetic transformation of animal cells.

We modified the Ca/EDTA procedure for the production of liposomes [Papahadjopoulos, Vail, Jacobson & Poste (1975) Biochim. Biophys. Acta 394, 483-491] to entrap intact DNA molecules of very high molecular mass into large unilamellar phospholipid vesicles. The use of DNA-protein complexes and phage particles instead of naked linear DNA increases the efficiency of entrapment and protects the integrity of DNA molecules. We investigated the interaction of mammalian cells with liposome-encapsulated recombinant lambda bacteriophages carrying marker genes. The liposomes bind surprisingly fast to the cellular surface and are taken up by the cells. A significant proportion of the encapsulated DNA is transported to and soon located in or around the nuclei. Experiments prove that these liposomes can be used for the genetic transformation of mammalian cells.     

Homologous recombination of exogenous DNA fragments with genomic DNA in somatic cells of mice.

We compared liposomes and empty viral capsids for their use as vehicles for DNA transfer into cells and animals. DNA binding capacity was high for liposomes, but DNase I protection of DNA bound to liposomes was only moderate in comparison to DNA incorporated into viral capsids. Cellular uptake of radiolabeled and physiologically active DNA was also compared. For animal studies we chose an endogenous retroposon as target gene. To identify recombinational events we replaced a part of this gene with an artificial sequence not present in the mouse genome. The recombination rate for DNA fragments transfected in Polyoma capsids in live mice was higher than for liposome mediated transfection. Homologous recombination could be observed for both DNA transfer methods, mediated by positively charged liposomes (DOTMA) and by empty Polyoma viral capsids.     

Cationic liposomes enhance targeted delivery and expression of exogenous DNA mediated by N-terminal modified poly(L-lysine)-antibody conjugate in mouse lung endothelial cells.

A new and improved system for targeted gene delivery and expression is described. Transfection efficiency of N-terminal modified poly(L-lysine) (NPLL) conjugated with anti-thrombomodulin antibody 34A can be improved by adding to the system a lipophilic component, cationic liposomes. DNA, antibody conjugate and cationic liposomes form a ternary electrostatic complex which preserves the ability to bind specifically to the target cells. At the same time the addition of liposomes enhance the specific transfection efficiency of antibody-polylysine/DNA binary complex by 10 to 20-fold in mouse lung endothelial cells in culture.     

Efficient Encapsulation of Plasmid DNA in Anionic Liposomes by a Freeze/Thaw-Extrusion Procedure

Abstract

In this study we investigated whether intact plasmid DNA can be efficiently encapsulated in anionic liposomes prepared by freeze/thaw and extrusion techniques. There is controversy about this method of DNA encapsulation, especially as to whether DNA remains intact and retains its biological activity during extrusion. A solution containing supercoiled plasmid pCMVβ (7164 base pairs) was added to dry lipid films, and after freezing and thawing, the suspension was extruded through a filter with 0.2 μm pores. About 20% of the DNA became encapsulated, as evidenced by protection from degradation by endonuclease added externally. Plasmid isolated from the liposomes was structurally intact, and had essentially the same transfection activity as untreated DNA. These results show that plasmid DNA can be reliably and efficiently encapsulated in anionic liposomes by freeze/thaw and extrusion.     

Transformation of competent Bacillus subtilis cells by chromosomal and plasmid DNA incorporated in liposomes

Transformation with chromosomal and plasmid DNAs comprised in liposomes of different compositions was studied on competent cells of Bacillus subtilis. Transformation with chromosomal DNA comprised in liposomes appeared to constitute 1.1 to 1.5% of the control, and transformation with plasmid DNA in liposomes reaches 8 to 11%, as compared to the control. It has been revealed that absorbtion of chromosomal or plasmid DNA comprised in liposomes by competent cells is 1-2 orders higher than that of chromosomal or plasmid DNAs which are not contained in liposomes. Besides, chromosomal DNA in liposomes was found to be transferred to competent cells in the double-stranded form, while during common transformation without liposomes, the DNA transferred is single-stranded.     

Liposome-mediated DNA transfer in eukaryotic cells: Dependence of the transfer efficiency upon the type of liposomes used and the host cell cycle stage

The pBR322 plasmid containing the sequence encoding β-lactamase, the enzyme conferring resistance to ampicillin, was encapsulated in liposomes of different phospholipid composition and incubated with synchronized cells. In mitotic cells as compared to cells synchronized in G₁, twice as many exogeneous DNA molecules were found associated with the cell nuclear DNA, when fluid, neutral liposomes were used. These liposomes are taken up by the cells mainly via endocytosis. When fluid, negatively charged liposomes were used as carriers about the same number of exogeneous DNA molecules were found associated with the nuclear DNA both in mitotic and in G₁-synchronized cells. The efficiency for gene transfer of liposomes entering the cells by different mechanisms was further studied and expressed both by the fraction of the radioactive plasmid associated with the nuclear DNA and by the level of the β-lactamase activity detected in the transfected cells. It appears that liposomes entering the cells mainly via an energy-dependent mechanism are more efficient for this type of DNA transfer.     

Transfection of Lactobacillus bulgaricus protoplasts by bacteriophage DNA.

A protoplast transfection system has been developed for Lactobacillus bulgaricus. The procedure involves a polyethylene glycol-mediated fusion of bacteriophage DNA encapsulated in liposomes into mutanolysin-treated cells. With L. bulgaricus B004 and DNA isolated from the phage phi c5004, transfection reached a maximum when at least 95% of the cells were osmotically fragile. The incorporation of phage DNA into liposomes was essential; no transfectants were detected in the absence of liposomes. The largest number of transfectants was observed after longer periods (20 min) of fusion of mutanolysin-treated cells and liposomes with polyethylene glycol. The maximum efficiency of 5 x 10(7) PFU/microgram of DNA was reached after a 24-h incubation in growth media prior to plating transfected cells in an agar overlay to detect the appearance of plaques. A minimum of 4 h of incubation in growth medium after fusion was required to detect the production and release of virions. The possibility that the high frequencies observed were due to bursting of transfected cells and subsequent infection of additional cells was found not to be a factor. The number of transfectants observed was directly proportional to the quantity of DNA added. These results define conditions appropriate for the introduction of DNA into L. bulgaricus.     

Transfection of Lactobacillus bulgaricus protoplasts by bacteriophage DNA

A protoplast transfection system has been developed for Lactobacillus bulgaricus. The procedure involves a polyethylene glycol-mediated fusion of bacteriophage DNA encapsulated in liposomes into mutanolysin-treated cells. With L. bulgaricus B004 and DNA isolated from the phage phi c5004, transfection reached a maximum when at least 95% of the cells were osmotically fragile. The incorporation of phage DNA into liposomes was essential; no transfectants were detected in the absence of liposomes. The largest number of transfectants was observed after longer periods (20 min) of fusion of mutanolysin-treated cells and liposomes with polyethylene glycol. The maximum efficiency of 5 x 10(7) PFU/microgram of DNA was reached after a 24-h incubation in growth media prior to plating transfected cells in an agar overlay to detect the appearance of plaques. A minimum of 4 h of incubation in growth medium after fusion was required to detect the production and release of virions. The possibility that the high frequencies observed were due to bursting of transfected cells and subsequent infection of additional cells was found not to be a factor. The number of transfectants observed was directly proportional to the quantity of DNA added. These results define conditions appropriate for the introduction of DNA into L. bulgaricus.     

Nucleotide exchange in genomic DNA of rat hepatocytes using RNA/DNA oligonucleotides. Targeted delivery of liposomes and polyethyleneimine to the asialoglycoprotein receptor

Chimeric RNA/DNA oligonucleotides have been shown to promote single nucleotide exchange in genomic DNA. A chimeric molecule was designed to introduce an A to C nucleotide conversion at the Ser365 position of the rat factor IX gene. The oligonucleotides were encapsulated in positive, neutral, and negatively charged liposomes containing galactocerebroside or complexed with lactosylated polyethyleneimine. The formulations were evaluated for stability and efficiency in targeting hepatocytes via the asialoglycoprotein receptor. Physical characterization and electron microscopy revealed that the oligonucleotides were efficiently encapsulated within the liposomes, with the positive and negative formulations remaining stable for at least 1 month. Transfection efficiencies in isolated rat hepatocytes approached 100% with each of the formulations. However, the negative liposomes and 25-kDa lactosylated polyethyleneimine provided the most intense nuclear fluorescence with the fluorescein-labeled oligonucleotides. The lactosylated polyethyleneimine and the three different liposomal formulations resulted in A to C conversion efficiencies of 19-24%. In addition, lactosylated polyethyleneimine was also highly effective in transfecting plasmid DNA into isolated hepatocytes. The results suggest that both the liposomal and polyethyleneimine formulations are simple to prepare and stable and give reliable, reproducible results. They provide efficient delivery systems to hepatocytes for the introduction or repair of genetic mutations by the chimeric RNA/DNA oligonucleotides.     

Successful transfection of hepatoma cells after encapsulation of plasmid DNA into negatively charged liposomes

The application of conventional cationic liposomes/DNA complexes in gene transfer was hampered due to their large size, instability, and limited transfection site in vivo. In this report, we described a dialysis-based method and produced small, stable, and negatively charged DNA-containing liposomes composed of low content of cationic lipid and high content of fusogenic lipid. The liposomes were relatively spherical with a condensed core inside, and exhibited small size with narrow particle size distribution. The encapsulation efficiency of the liposomes was 42.53 +/- 2.29%. They were stable and showed enough protective ability to plasmid DNA from degradation after incubation with different amounts of DNase. Twenty-fold higher transfection efficiency for the liposomes was achieved when compared with that of naked plasmid DNA and no toxicities to hepatocellular carcinoma cells were observed. Our results indicate that the negatively charged DNA-containing liposomes can facilitate gene transfer in cultured cells, and may alleviate the drawbacks of the conventional cationic liposomes/DNA complexes for gene delivery in vivo.     

Entrapment of plasmid DNA in liposomes.

The entrapment of plasmid DNA (pMB9) and high molecular weight DNA into large unilamellar liposomes is described. The entrapment of DNA is specific and due to encapsulation of DNA into the aqueous compartment of liposomes. The entrapped Dna, resistant to deoxyribonuclease treatment, could be reisolated from liposomes intact and, as has been shown by transformation assay, it remains biologically active. The advantages of our method and possible applications are discussed.     

Biodistribution of liposome/DNA systems after subcutaneous and intraperitoneal inoculation

In this work, we analyzed protein interaction, cell toxicity, and biodistribution of liposome formulation for further possible applications as DNA vehicles in gene-therapy protocols. In relation to protein interaction, cationic liposomes showed the lowest protein interaction, but this parameter was incremented with DNA association. On the other hand, noncharged liposomes presented high protein interaction, but DNA association decreased this parameter. Protein interaction of polymeric liposomes did not change with DNA association. Cell toxicity of these three liposome formulations was low, cell death became present at concentrations higher than 0.5?mg/mL, and these concentrations were higher than those usually used in transfection assays. In the case of noncharged and polymeric liposomes, toxicity increased upon interaction with serum proteins. DNA/liposome-mediated tissue distribution was analyzed in Balb-c female mice. Results indicated that noncharged liposomes were able to deliver DNA to liver after intraperitoneal (i.p.) inoculation, while polymeric liposomes were able to deliver DNA to kidney by using the same inoculation route. Cationic liposomes were able to deliver DNA to a wide range of tissues by the i.p. route (e.g., liver, intestine, kidney, and blood). After subcutaneous inoculation, only cationic liposomes were able to deliver DNA to blood, but not the other two formulations within the detection limits of the method.     

Injection of DNA into liposomes by bacteriophage lambda

Small unilamellar vesicles (75-100 nm diameter) and large liposomes (greater than 1 micron in diameter) were prepared containing the lamB protein, an outer membrane protein of Escherichia coli and Shigella which serves as the receptor for bacteriophage lambda. Bacteriophage were observed to bind to these liposomes and vesicles by their tails and in most cases the heads of the bound bacteriophage appeared empty or partially empty of DNA. The lambda DNA was usually only partially ejected from the bacteriophage head when small unilamellar liposomes were used, presumably because the vesicles are too small to contain all the DNA. The partially ejected DNA was not susceptible to DNase unless the vesicle bilayer was first disrupted suggesting that DNA injection of phage DNA into the vesicle had occurred. After disruption of these vesicles on electron microscope grids, the bacteriophage are seen to have partially empty heads and a small mass of DNA associated with their tails. Using larger liposomes prepared by the fusion of lamB bearing vesicles with polyethylene glycol and n-hexyl bromide, the heads of most of the bound bacteriophage appeared to be completely empty of DNA. Disruption of these preparations on electron microscope grids revealed circular arrays of empty-headed bacteriophage surrounding DNA which had apparently been contained within the intact liposomes. These results indicate that high molecular weight DNA can be entrapped within liposomes with high efficiency by ejection from bacteriophage lambda. The possible use of these DNA-containing liposomes to facilitate gene transfer in eukaryotic cells is discussed.     

Induction of apoptosis in macrophages by cationic liposomes

The effects of liposomes on apoptosis in macrophages were evaluated from DNA content and DNA fragmentation. Cationic liposomes composed of different kinds of cationic lipids induced apoptosis in mouse splenic macrophages and the macrophage-like cell line, RAW264.7 cells. Generation of reactive oxygen radicals from macrophages treated with cationic liposomes was detected using flow cytometry, and further apoptosis was inhibited by the addition of oxidant scavenger, N-acetylcysteine. From these findings, the production of reactive oxygen species may be important in the regulation of apoptosis induced by cationic liposomes.     

Genetic transformation of yeast protoplasts with DNA encapsulated in liposomes

Abstract Protoplasts of auxotrophic strains of Saccharomyces cerevisiae could be transformed to prototrophy with plasmid DNA encapsulated in liposomes. With negatively charged liposomes, the transformation efficiency was higher than with naked DNA.     

Evaluation of the high-pressure extrusion technique as a method for sizing plasmid DNA-containing cationic liposomes

A promising strategy to improve the immunogenic potential of DNA vaccines is the formulation of plasmid DNA (pDNA) with cationic liposomes. In this respect, particle size may be of crucial importance. This study aimed at the evaluation of high-pressure extrusion as a method for sizing cationic liposomes after entrapment of pDNA. This is a well-known sizing method for liposomes, but so far, it has not been applied for liposomes that are already loaded with pDNA. Liposomes composed of egg PC, DOTAP, and DOPE with entrapped pDNA were prepared by the dehydration-rehydration method and subjected to various extrusion cycles, comparing different membrane pore sizes and extrusion frequencies. At optimized extrusion conditions, liposome diameter (Zave) and polydispersity index (PDI) were reduced from 560 nm and 0.56-150 nm and 0.14 respectively, and 35% of the pDNA was retained. Importantly, gel electrophoresis and transfection experiments with pDNA extracted from these extruded liposomes demonstrated the preservation of the structural and functional integrity of the pDNA. The reduction in size resulted in enhanced transfection of HeLa cells, as detected by functional expression of the fluorescent protein, eGFP. In addition, these liposomes were able to stimulate Toll-like receptor 9, indicating efficient endosomal uptake and release of the included pDNA. In conclusion, high-pressure extrusion is a suitable technique to size cationic liposomes with entrapped pDNA and allows preparation of well-defined nanosized pDNA-liposomes, with preserved pDNA integrity. Their improved transfection efficiency and ability to activate an important pattern-recognition receptor are favorable properties for DNA vaccine delivery vehicles.