The role of helper lipids in cationic liposome-mediated gene transfer.

In the procedure for cationic liposome-mediated transfection, the cationic lipid is usually mixed with a "helper lipid" to increase its transfection potency. The importance of helper lipids, including dioleoylphosphatidylcholine (DOPC) and phosphatidylethanolamine (dioleoyl PE), DO was examined. Freeze-fracture electron microscopy of DNA:cationic complexes containing the pSV-beta-GAL plasmid DNA, the cationic lipid dioleoyl trimethylammonium propane, and these helper lipids showed that the most efficient mixtures were aggregates of ensheathed DNA and fused liposomes. PE-containing complexes aggregated rapidly when added to culture media containing polyanions, whereas PC-containing complexes did not. However, more granules of PC-containing complexes were formed on cell surfaces after the complexes were added to Chinese hamster ovary (CHO) cells in transfection media. Pronase treatment inhibited transfection, whereas dilute poly-L-lysine enhanced transfection, indicating that the attachment of DNA:liposome complexes to cell surfaces was mediated by electrostatic interaction. Fluorescence spectroscopy studies confirmed that more PC-containing complexes than PE-containing complexes were associated with CHO cells, and that more PC-containing complexes were located in a low pH environment (likely to be within endosomes) with time. Cytochalasin-B had a stronger inhibitory effect on PC-containing liposome-mediated than on PE-containing liposome-mediated transfection. Confocal microscopic recording of the fluorescently label lipid and DNA uptake process indicated that many granules of DNA:cationic liposome complexes were internalized as a whole, whereas some DNA aggregates were left out on the cell surfaces after liposomes of the complexes fused with the plasma membranes. For CHO cells, endocytosis seems to be the main uptake pathway of DNA:cationic liposome complexes. More PC-containing granules than PE-containing granules were formed on cell surfaces by cytoskeleton-directed membrane motion, after their respective DNA:liposome complexes attached to cell surfaces by electrostatic means. Formation of granules on the cell surface facilitated and/or triggered endocytosis. Fusion between cationic liposomes and the cell membrane played a secondary role in determining transfection efficiency.     

Gene transfection efficiency of tracheal epithelial cells by DC-chol-DOPE/DNA complexes.

We evaluated the transfection efficiency of five different cationic liposome/plasmid DNA complexes, during the in vitro gene transfer into human epithelial tracheal cell lines. A dramatic correlation between the transfection efficiency and the charge ratio (positive charge of liposome to negative charge of DNA) has been found. DC-Chol-DOPE was found to be the most effective liposome formulation. Therefore, a morphological and structural analysis of DC-Chol-DOPE liposomes and DC-Chol-DOPE/DNA complexes, has been performed by transmission electron microscopy (TEM) and by confocal laser scanning microscopy (CLSM), respectively. The process of interaction between DC-Chol-DOPE/DNA complexes and human epithelial tracheal cells has been studied by CLSM. These results raise some issues for in vivo gene therapy.     

Colloidal structure and stability of DNA/polycations polyplexes investigated by small angle scattering

Polyplexes of short DNA-fragments (300 b.p., 100 nm) with tailor-made amine-based polycations of different architectures (linear and hyperbranched) were investigated in buffer solution as a function of the mixing ratio with DNA. The resulting dispersed polyplexes were characterized using small-angle neutron and X-ray scattering (SANS, SAXS) as well as cryo-TEM with respect to their mesoscopic structure and their colloidal stability. The linear polyimines form rather compact structures that have a high tendency for precipitation. In contrast, the hyperbranched polycation with enzymatic-labile pentaethylenehexamine arms (PEHA) yields polyplexes colloidally stable for months. Here the polycation coating of DNA results in a homogeneous dispersion based on a fractal network with low structural organization at low polycation amount. With increasing polycation, bundles of tens of aligned DNA rods appear that are interconnected in a fractal network with a typical correlation distance on the order of 100 nm, the average length of the DNA used. With higher organization comes a decrease in stability. The 3D network built by these beams can still exhibit some stability as long as the material concentration is large enough, but the structure collapses upon dilution. SAXS shows that the complexation does not affect the local DNA structure. Interestingly, the structural findings on the DNA polyplexes apparently correlate with the transfection efficiency of corresponding siRNA complexes. In general, these finding not only show systematic trends for the colloid stability, but may allow for rational approaches to design effective transfection carriers.     

Zeta potential of transfection complexes formed in serum-free medium can predict in vitro gene transfer efficiency of transfection reagent

We have tested the zeta potential (zeta, the surface charge density) of transfection complexes formed in serum-free medium as a rapid and reliable technique for screening transfection efficiency of a new reagent or formulation. The complexes of CAT plasmid DNA (1 microgram) and DC-chol/DOPE liposomes (3-20 nmol) were largely negatively charged (zeta=-15 to -21 mV), which became neutral or positive as 0.5 microgram or a higher amount of poly-L-lysine (PLL, MW 29300 or MW 204000) was added (-3.16+/-3.47 to +6.04+/-2.23 mV). However, the complexes of CAT plasmid DNA (1 microgram) and PLL MW 29300 (0.5 microgram or higher) were neutral or positively charged (-3.22+/-2.3 to +6.55+/-0.64 mV), which remained the same as 6.6 nmol of the liposomes was added. The complexes formed between two positively charged compounds, PLL MW 29300 (0.5 microgram) and the liposomes (3-20 nmol), were as closely positively charged as DNA/PLL or DNA/liposomes/PLL complexes (+3.31+/-0.41 to 7.16+/-1.0 mV). These results indicate that PLL determined the overall charge of the DNA/liposome/PLL ternary complexes. The complexes formed with histone (0.75 microgram or higher) were also positively charged, whose transfection activity was as high as PLL MW 29300. However, the complexes formed with protamine or PLL MW 2400 remained negatively charged. These observations are in good agreement with the transfection activity of the formulation containing each polycationic polymer. The presence of PLL MW 29300 did not change the hydrodynamic diameter of DNA/liposome/PLL complexes (d(H)=275-312 nm). The complexes made of different sizes of PLL (MW 2400 and 204000) also did not significantly change their size. This suggests that DNA condensation may not be critical. Therefore, zeta of the transfection complex can predict the transfection efficiency of a new formulation or reagent.     

Use of a quaternary ammonium detergent in liposome mediated DNA transfection of mouse L-cells

Sonicated liposomes composed of dioleoylphosphatidylethanolamine (DOPE) and a quaternary ammonium detergent (dodecyl-, tetradecyl-, or cetyl-trimethylammonium bromide) mediates functional transfer of pSV2 CAT plasmid DNA to mouse L929 fibroblasts. Successful transfection was determined by assaying for chloramphenicol acetyltransferase activity in cell lysates collected 40 h after exposure to the lipid-DNA complexes. Liposomes prepared with the quaternary ammonium detergents were less toxic than the free detergents at the same concentrations and were more efficient in their delivery of the plasmid DNA to the cells. Analysis of the three detergents in combination with the lipid showed that cetyltrimethylammonium bromide was least toxic to the cells. This detergent, at a minimal concentration of 20 mol% in DOPE, allowed for stable liposome preparations and efficient transfection. Optimal efficiency of transfection occurred with 30 micrograms of DNA. Further increases in the DNA concentration caused a decrease in the transfection efficiency, perhaps due to charge repulsions between the liposomes now saturated with negatively charged DNA and the negatively charged cell surface. The transfection activity of the liposome was limited by its cytotoxicity at high liposome concentrations. These results are compared with that of the Lipofectin, another positively charged liposome preparation which is commercially available. Although the overall transfection activity of the liposome containing the quaternary ammonium detergent is somewhat lower than that of the Lipofectin, it may serve as an inexpensive and convenient alternative.     

Polyethylenimine of various molecular weights as adjuvant for transfection mediated by cationic liposomes

Over the last years significant progress has been made in non-viral gene delivery mediated by cationic liposomes. However, the results obtained are still far from being satisfactory regarding transfection efficiency, particularly when compared to that achieved using viral vectors. We have previously demonstrated that association of transferrin with cationic liposomes significantly improves transfection in a large variety of cells, both in vitro and in vivo. In this work, several strategies have been explored in order to further improve transfection mediated by transferrin-associated lipoplexes. To this regard, the effect on transfection of pre-condensation of DNA with polyethylenimine of low MWs (2.7, 2.0 and 0.8 KDa) at various N/P ratios, lipid composition, cationic lipid/DNA (+/-) charge ratio and the presence of a surfactant in the lipoplexes was investigated. Two different modes for preparing the liposomes were tested and the extent of cell association of their complexes with DNA as well as their capacity to protect the carried DNA were evaluated. Our results show that complexes generated from cationic liposomes prepared by the ethanol injection method in which the carried DNA was pre-condensed with low MW polyethylenimine are highly efficient in mediating transfection. The differential modulating effect observed upon association of transferrin to various liposome formulations on transfection mediated by the polyethylenimine-complexes suggests that these complexes enter into the cells through different pathways (involving clathrin versus caveolin), most likely by taking advantage of their intrinsic biophysical properties to escape from the endosome to the cytosol.     

Preparation, characterization and transfection efficiency of cationic PEGylated PLA nanoparticles as gene delivery systems

The cationic polylactic acid (PLA) nanoparticle has emerged as a promising non-viral vector for gene delivery because of its biocompatibility and biodegradability. However, they are not capable of prolonging gene transfer and high transfection efficiency. In order to achieve prolonged delivery of cationic PLA/DNA complexes and higher transfection efficiency, in this study, we used copolymer methoxypolyethyleneglycol-PLA (MePEG-PLA), PLA and chitosan (CS) to prepare MePEG-PLA-CS NPs and PLA-CS NPs by a diafiltration method and prepared NPs/DNA complexes through the complex coacervation of nanoparticles with the pDNA. The object of our work is to evaluate the characterization and transfection efficiency of MePEG-PLA-CS versus PLA-CS NPs. The MePEG-PLA-CS NPs have a zeta potential of 15.7 mV at pH 7.4 and size under 100 nm, while the zeta potential of PLA-CS NPs was only 4.5 mV at pH 7.4. Electrophoretic analysis suggested that both MePEG-PLA-CS NPs and PLA-CS NPs with positive charges could protect the DNA from nuclease degradation and cell viability assay showed MePEG-PLA-CS NPs exhibit a low cytotoxicity to normal human liver cells. The potential of PLA-CS NPs and MePEG-PLA-CS NPs as a non-viral gene delivery vector to transfer exogenous gene in vitro and in vivo were examined. The pDNA being carried by MePEG-PLA-CS NPs, PLA-CS NPs and lipofectamine could enter and express in COS7 cells. However, the transfection efficiency of MePEG-PLA-CS/DNA complexes was better than PLA-CS/DNA and lipofectamine/DNA complexes by inversion fluorescence microscope and flow cytometry. It was distinctively to find that the transfection activity of PEGylation of complexes was improved. The nanoparticles were also tested for their ability to transport across the gastrointestinal mucosa in vivo in mice. In vivo experiments showed obviously that MePEG-PLA-CS/DNA complexes mediated higher gene expression in stomach and intestine of BALB/C mice compared to PLA-CS/DNA and lipofectamine/DNA complexes. These results suggested that MePEG-PLA-CS NPs have favorable properties for non-viral gene delivery.     

Transfection property of a new cholesterol-based cationic lipid containing tri-2-hydroxyethylamine as gene delivery vehicle

A novel cholesterol-based cationic lipid containing a tri-2- hydroxyethylamine head group and ether linker (Chol- THEA) was synthesized and examined as a potent gene delivery vehicle. In the preparation of cationic liposome, the addition of DOPE as helper lipid significantly increased the transfection efficiency. To find the optimum transfection efficiency, we screened various weight ratios of DOPE and liposome/DNA (N/P). The best transfection efficiency was found at the Chol-THEA:DOPE weight ratio of 1:1 and N/P weight ratio of 10~15. Most of the plasmid DNA was retarded by this liposome at the optimum N/P weight ratio of 10. The transfection efficiency of Chol-THEA liposome was compared with DOTAP, Lipofectamine, and DMRIE-C using the luciferase assay and GFP expression. Chol-THEA liposome with low toxicity had better or similar potency of gene delivery compared with commercial liposomes in COS-7, Huh-7, and MCF-7 cells. Therefore, Chol-THEA could be a useful non-viral vector for gene delivery.     

Unique features of a pH-sensitive fusogenic peptide that improves the transfection efficiency of cationic liposomes

BACKGROUND: One of the critical steps in intracellular gene delivery using cationic liposomes is the endosomal escape of the plasmid/liposome complexes to the cytosol. The addition of GALA, a pH-sensitive fusogenic peptide, is a promising method to accelerate this step in order to enhance the expression of the desired proteins. Detailed studies on the methods of enhancement would broaden the horizon of its application. METHODS: Using representative commercially available cationic liposomes (Lipofectin, Lipofectamine, and Lipofectamine 2000), the effects of GALA on transfection efficiency were studied by luciferase assay and confocal microscopic observations. RESULTS: A concentration-dependent increase in the transfection efficiency was observed for GALA. Addition of 0.1 microM GALA to the plasmid/liposome complex significantly increased the transfection efficiency, especially in the case of Lipofectin, but higher concentration of GALA decreased transfection efficiency. Successful reduction in the liposomal dosage was attained by employing GALA while maintaining a high transfection efficiency. Interestingly, although the transfection efficiency was higher in the presence of GALA, a lower amount of the plasmid DNA was taken up by the cells. Confocal microscopic observations of the rhodamine-labeled plasmid did not show a significant difference in the cellular localization among cells incubated in the presence or absence of GALA, suggesting that a slight increase in GALA-induced release of the plasmid to the cytosol may cause a significant change in the transfection efficiency. CONCLUSION: The unique features of GALA to mediate improved transfection efficiencies were identified.     

Lipid composition of cationic nanoliposomes implicate on transfection efficiency

Abstract

Cationic liposome (CL)-DNA complexes (lipoplexes) have appeared as leading nonviral gene carriers in worldwide gene therapy clinical trials. Arriving at therapeutic dosages requires the full understanding of the mechanism of transfection. However, using CLs to deliver therapeutic nucleic acids and drugs to target organs have some problems, including low transfection efficiency. The aim of this study was developing novel CLs containing four neutral lipids; cholesterol, 1,2-dioleoyl phosphatidylethanolamine, distearoylphosphatidylcholine and dipalmitoylphosphatidylcholine as a helper lipid and dimethyl dioctadecyl ammonium bromide as a cationic lipid to increase transfection efficiency. We have investigated the correlation between number of lipid composition and transfection efficiency. The morphology, size and zeta potential of liposomes and lipoplexes were measured and lipoplexes formation was monitored by gel retardation assay. Transfection efficiency was assessed using firefly luciferase reporter assay. It was found that transfection efficiency markedly depended on liposome to plasmid DNA (pDNA) weight ratio, lipid composition and efficiency of pDNA entrapment. High transfection efficiency of plasmid by four component lipoplexes was achieved. Moreover, lipoplexes showed lower transfection efficiency and less cytotoxicity compared to Lipofectamine?. These results suggest that lipid composition of nanoliposomes is an important factor in control of their physical properties and also yield of transfection.     

Polyethylenimine-graft-poly(ethylene glycol) copolymers: influence of copolymer block structure on DNA complexation and biological activities as gene delivery system

For two series of polyethylenimine-graft-poly(ethylene glycol) (PEI-g-PEG) block copolymers, the influence of copolymer structure on DNA complexation was investigated and physicochemical properties of these complexes were compared with the results of blood compatibility, cytotoxicity, and transfection activity assays. In the first series, PEI (25 kDa) was grafted to different degrees of substitution with PEG (5 kDa) and in the second series the molecular weight (MW) of PEG was varied (550 Da to 20 kDa). Using atomic force microscopy, we found that the copolymer block structure strongly influenced the DNA complex size and morphology: PEG 5 kDa significantly reduced the diameter of the spherical complexes from 142 +/- 59 to 61 +/- 28 nm. With increasing degree of PEG grafting, complexation of DNA was impeded and complexes lost their spherical shape. Copolymers with PEG 20 kDa yielded small, compact complexes with DNA (51 +/- 23 nm) whereas copolymers with PEG 550 Da resulted in large and diffuse structures (130 +/- 60 nm). The zeta-potential of complexes was reduced with increasing degree of PEG grafting if MW >or= 5 kDa. PEG 550 Da did not shield positive charges of PEI sufficiently leading to hemolysis and erythrocyte aggregation. Cytotoxicity (lactate dehydrogenase assay) was independent of MW of PEG but affected by the degree of PEG substitution: all copolymers with more than six PEG blocks formed DNA complexes of low toxicity. Finally, transfection efficiency of the complexes was studied. The combination of large particles, low toxicity, and high positive surface charge as in the case of copolymers with many PEG 550 Da blocks proved to be most efficient for in vitro gene transfer. To conclude, the degree of PEGylation and the MW of PEG were found to strongly influence DNA condensation of PEI and therefore also affect the biological activity of the PEI-g-PEG/DNA complexes. These results provide a basis for the rational design of block copolymer gene delivery systems.     

Dilution of reporter gene with stuffer DNA does not alter the transfection efficiency of polyethylenimines

BACKGROUND: Polyethylenimines (PEIs) are among the most efficient non-viral gene transfer agents developed so far. However, transfections with these polymers were shown to require a very high copy number of plasmid DNA per cell to achieve gene expression. Here, we investigate whether it is possible to reduce the amount of plasmid DNA while keeping a high transfection efficiency. METHODS: Transfection experiments were performed under various conditions in order to study the interdependence between the amount of reporter DNA, the amine-to-phosphate ratio and the transfection efficiency. RESULTS: When suboptimal amounts of linear PEI 22 kDa/DNA complexes were used for transfection, a severe reduction in reporter gene expression was observed. On the other hand, for optimal amounts of PEI/DNA complexes more than half of the reporter gene can be replaced by carrier DNA or polyglutamic acid without substantially decreasing the transfection efficiency of the polymer both in cultured cells and after systemic administration in mice. When used under the same in vitro experimental conditions, the lipospermine DOGS, but not the monocationic lipid DOTAP, gave similar results. CONCLUSIONS: Taken together, our data suggest that the activity of compounds with endosome-buffering capacities, such as PEIs and lipospermines, requires a threshold amount of transfection agent. In addition, our results indicate that, in many gene transfer situations, it will be possible to lower the dose of active plasmid thus reducing costs and the risk of immune stimulation triggered by bacterial DNA.     

脂质体介导外源基因体外转染牛胎儿成纤维细胞条件的优化

通过脂质体（FuGENE-6）介导,将真核表达载体pEGFP-C1成功导入体外培养的牛胎儿成纤维细胞,探讨影响外源基因转染效率的参数,如DNA和脂质体的用量、转染的细胞数量以及细胞暴露于DNA与脂质体复合物的时间长度。通过实验发现,绿色荧光蛋白（green fluorescent protein,GFP）基因的表达随DNA、脂质体量的增加而增加,延长细胞暴露时间反而使转染效率下降,转染细胞数适当才能得到较高的转化率。 Optimization of Parameters of Exogene Transfection of Bovine Fetal Fibroblasts in vitro Mediated by Liposome LI Yang,WU Kai-feng,GUO Xu-dong,GUO Ji-tong,BOU Shor-gan The Research Center for Laboratory Animal Science of Inner Mongolia University,The Key Laboratory of Ministry of Education of China for Mammal Reproduction Biology and Biotechnology,Huhhot 010021,China Abstract:pEGFP-C1 eucaryon expression vector was successfully transfected by liposome into bovine fetal fibroblasts.We investigated the effect of parameter such as the dose of DNA and liposome,number of cell transfected and exposure time of the cell to the DNA-liposome complexes.It was indicated that GFP（green fluorescent protein）expression was enhanced as the dose of DNA and liposome increased and on decline as the exposure time was prolonged.The improvement of transfection efficiency depent on the suitable cell number. Key words：liposome; GFP; bovine fetal fibroblasts; transfection     

Cationic liposome and plasmid DNA complexes formed in serum-free medium under optimum transfection condition are negatively charged

In medium where in vitro transfection is routinely performed, DC-chol liposomes alone were nearly neutral, whereas the DC-chol liposome/DNA complexes were largely negatively charged which changed only slightly at all [liposome]/[DNA] ratios (zeta=-27.1 to -21.8 mV). Three other commercial transfection reagents, Lipofectin(R), LipofectAMINE 2000, and SuperFect, were also largely negatively charged when complexed with DNA. The aggregation of liposomes in medium was prevented by the addition of DNA. Incubation of the complexes in medium did not change their size, charge or lipofection activity for 30 min. These results suggest that, in medium, the liposome/DNA complexes were formed at the time of mixing with negative charges.     

Multilamellar Cationic Liposomes are Efficient Vectors for in Vitro Gene Transfer in Serum

Abstract

Multilamellar vesicles (MLVs) containing the cationic lipid DOTAP were used as vectors to lipofect a number of culture cell lines in the presence of serum. The lipofection efficiency of lipoplexes made of MLVs and the plasmid pSV-β galactosidase are much less sensitive to the lipofection-inhibitory effect of serum than the conventionally used lipoplexes made of sonicated small unilamellar vesicles (SUVs). In order to determine the factors favoring the lipofection efficiency of MLVs, we measured the size, as well as the cellular association and uptake of MLV and SUV lipoplexes containing DOTAP alone or DOTAP:DOPE (1:1). Electron microscope images of these complexes were taken to confirm their structure and size. The single most important factor that correlates with transfection efficiency in serum is the size of the lipoplex. SUV lipoplexes remain smaller than 300 nm in the presence of serum, and the lipofection efficiencies are low. MLV lipoplexes are larger (>300 nm) and the lipofection efficiency, as well as cellular association and uptake, are much higher than those of SUV lipoplexes. Exceptions are those lipoplexes made of MLVs of DOTAP and DOPE (1:1) combined with DNA at higher charge ratios, which form hexagonal structures and show poor lipofection as well as cellular association and uptake, even if their lipoplex size exceeds 300 nm. This finding lends credence to our theory of the serum inhibition effect upon lipofection, and suggests ways to improve the transfection efficiency in the presence of serum, by fabricating lipoplexes of defined sizes.     

Linear polyethyleneimine grafted to a hyperbranched poly(ethylene glycol)-like core: a copolymer for gene delivery

A block copolymer of a hyperbranched poly(ethylene glycol)-like core and linear polyethylenimine (HBP) was synthesized by a facile synthetic route that included (1) a single-step cationic copolymerization of diepoxy and polyhydroxyl monomers, (2) derivatization of hydroxyl groups of the core HBPEG copolymer with either tosyl or chloromethylbenzoyl chlorides resulting in a corresponding macroinitiator, and (3) synthesis of HBPEG-block-poly(alkyl oxazolines). HBPEG-block-linear polyethyleneimine (HBP) was obtained by hydrolysis of HBPEG-block-poly(alkyl oxazolines). Linear PEI-bearing hyperbranched polycations (HBP) had lower inherent toxicity in cell culture than PEG-grafted linear polyethyleneimines (PEGLPEI). PEGLPEI formed a complex with DNA with an average diameter of 250 nm. The complexes were loosely condensed and formed aggregates and precipitates during storage. By contrast, hyperbranched polycations (HBP) formed approximately 50 nm nanocomplexes with DNA that were stable for several weeks and showed resistance to DNAse I-mediated degradation. The 'inverted' block copolymers showed several orders of magnitude higher transfection efficiency than PEGLPEI in vitro. Because of the biocompatibility and higher transfection efficiency, the 'inverted' block copolymer merits further investigation as a gene carrier.     

DNA internalized via caveolae requires microtubule-dependent, Rab7-independent transport to the late endocytic pathway for delivery to the nucleus

Using cationic liposomes to mediate gene delivery by transfection has the advantages of improved safety and simplicity of use over viral gene therapy. Understanding the mechanism by which cationic liposome:DNA complexes are internalized and delivered to the nucleus should help identify which transport steps might be manipulated in order to improve transfection efficiencies. We therefore examined the endocytosis and trafficking of two cationic liposomes, DMRIE-C and Lipofectamine LTX, in CHO cells. We found that DMRIE-C-transfected DNA is internalized via caveolae, while LTX-transfected DNA is internalized by clathrin-mediated endocytosis, with both pathways converging at the late endosome or lysosome. Inhibition of microtubule-dependent transport with nocodazole revealed that DMRIE-C:DNA complexes cannot enter the cytosol directly from caveosomes. Lysosomal degradation of transfected DNA has been proposed to be a major reason for poor transfection efficiency. However, in our system dominant negatives of both Rab7 and its effector RILP inhibited late endosome to lysosome transport of DNA complexes and LDL, but did not affect DNA delivery to the nucleus. This suggests that DNA is able to escape from late endosomes without traversing lysosomes and that caveosome to late endosome transport does not require Rab7 function. Lysosomal inhibition with chloroquine likewise had no effect on transfection product titers. These data suggest that DMRIE-C and LTX transfection complexes are endocytosed by separate pathways that converge at the late endosome or lysosome, but that blocking lysosomal traffic does not improve transfection product yields, identifying late endosome/lysosome to nuclear delivery as a step for future study.     

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.     

Generic technique to generate large branched DNA complexes

The inherent self-recognition properties of DNA have led to its use as a scaffold for various nanotechnology self-assembly applications, with macromolecular complexes, metallic and semiconducting nanoparticles, proteins, inter alia, being assembled onto a designed DNA scaffold. Such structures may typically comprise a number of DNA molecules organized into macromolecules. Many studies have used synthetic methods to produce the constituent DNA molecules, but this typically constrains the molecules to be no longer than around 100 base pairs (30 nm). However, applications that require larger self-assembling DNA complexes, several tens of nanometers or more, need to be generated by other techniques. Here, we present a generic technique to generate large linear, branched, and/or circular DNA macromolecular complexes. The effectiveness of this technique is demonstrated here by the use of Lambda Bacteriophage DNA as a template to generate single- and double-branched DNA structures approximately 120 nm in size.