Jing-Ping Yang

Effect of non-ionic surfactants on the formation of DNA/emulsion complexes and emulsion-mediated gene transfer.

AbstractPurpose. To study the structure-function relationship of non-ionic surfactants in emulsion-mediated gene delivery. Methods. Four different types of non-ionic surfactants including Tween, Span, Brij and pluronic copolymers were used as co-emulsifiers for preparation of emulsions composed of Castor oil, dioleoylphosphatidylethanolamine (DOPE) and 3β[N-(N′, N′-dimethylaminoethane) carbamoyl] cholesterol (DC-Chol). The effect of different surfactants on the formation of DNA/emulsion complexes and transfection activity were analyzed using plasmid DNA containing luciferase cDNA as a reporter gene. Results. Non-ionic surfactants containing branched polyoxyethylene chains as the hydrophilic head group were more effective in preventing the formation of large DNA/emulsion complexes than those containing one or no polyoxyethylene chain. All emulsion formulations except those containing Brij 700 exhibited high activity in transfecting mouse BL-6 cells in the absence of serum. In the presence of serum, however, transfection activity of each formulation varied significantly. Emulsions containing Tween, Brij 72, pluronic F68 and F127 demonstrated increased activity in transfecting cells in the presence of 20% serum. In contrast to emulsions containing Span, long chain polyoxyethylene of Brij showed decreased transfection activity. The particle size of the DNA/emulsion complexes and their ability to transfect cells are dependent on the concentration of non-ionic surfactant in the formulation. Conclusions. The structure of the hydrophilic head group of the non-ionic surfactants in the emulsion is important in determining how DNA molecules interact with emulsions and the extent to which DNA is transferred inside the cell.

New Cationic Lipid Formulations for Gene Transfer

AbstractPurpose. To develop appropriate dosage forms of DNA for gene delivery. Methods. 3β[N-(N′, N′ dimethylaminoethane) carbamoyl] cholesterol (DC-Chol) was mixed either with Tween 80 alone, or with additional lipid components including castor oil and phosphatidylcholine (PC) or dioleoylphosphatidylethanolamine (DOPE) to make different lipid formulations. The particle size and the physical stability of the formulations upon mixing with plasmid DNA containing the luciferase cDNA were examined using laser light scattering measurement. The transfection activity of the DNA/lipid complexes was tested in presence or absence of serum using a cell culture system. Results. We demonstrated that many favorable properties as a gene carrier could be achieved by formulating DNA into new dosage forms using Tween 80 as the major emulsifier. Compared to the cationic liposomes, these new formulations transfected different cell lines with an equivalent or higher efficiency. Not only are they resistant to serum, but also form stable DNA complexes which could be stored for longer periods of time without losing transfection activity. Conclusions. Cationic lipids formulated into different lipid formulations using Tween 80 as a surfactant appeared to have more favorable physical and biological activities than traditional cationic liposomes as a carrier for gene delivery.

A novel T7 RNA polymerase autogene for efficient cytoplasmic expression of target genes.

Inefficient nuclear transport of plasmid DNA continues to be a problem in nonviral vector-mediated gene transfer. This has made the cytoplasmic expression system an increasingly attractive idea. We have developed a new T7 RNA polymerase autogene for cytoplasmic expression containing both a CMV and a T7 promoter. The pCMV/T7-T7pol autogene does not encounter the problems associated with previously used autogenes. For instance, pCMV/T7-T7pol is easily amplified and purified from bacteria. Furthermore, the CMV promoter is used to drive the first round of synthesis of T7 RNA polymerase, thus negating the use of purified enzyme in the transfection complex. The endogenous T7 RNA polymerase produced from the CMV promoter could then act on the T7 promoter of pCMV/T7-T7pol in an autoregulatory mechanism. pCMV/T7-T7pol induces higher, more sustained levels (>7 days) of reporter gene expression than that observed with the previously used autogene pT7 AUTO 2C− or with the nuclear expression system pCMV-CAT. This seems to be due to the high levels of T7 RNA polymerase protein that are detected in cells transfected with pCMV/T7-T7pol. This vector also functions as an efficient autogene since at least 50 times more mRNA is transcribed from the cytoplasmic T7 promoter as compared with the nuclear CMV promoter in pCMV/T7-T7pol. Therefore, pCMV/T7-T7pol could replace existing autogenes for regeneration of T7 RNA polymerase and efficient target gene expression.