Leaf Huang

Structures formed during interaction of cationic liposomes and plasmid DNA were studied by freeze-fracture electron microscopy and their morphology was found to be dependent on incubation time and DNA concentration. These structures were formed with liposomes composed of DC-Chol and DOPE after 30 min incubation at DNA:lipid concentrations encompassing maximal transfection activity. They resembled liposome complexes (meatballs) and additionally bilayer-covered DNA tubules (spaghetti), whereby the DNA-tubules were found to be connected to the liposome complexes as well as occurring free in the suspension. At later times and higher DNA-to-liposome ratios the complexes grow larger while their membranes become discontinuous, allowing the self-encapsulation of the DNA. The relative transfection potency of the various morphologically distinct structures is discussed.

Expression of bacteriophage T7 RNA polymerase in mammalian cells can efficiently drive the transcription of a foreign gene controlled by the T7 promoter (Elroy-Stein et al., Proc. Natl. Acad. Sci. USA. 86, 6126-6130, 1989). We have tested the hypothesis that purified T7 RNA polymerase can be co-delivered into mammalian cells together with a reporter gene (chloramphenicol acetyltransferase, CAT) controlled by the T7 promoter (pT7-EMC-CAT) using DC-chol cationic liposomes. Indeed, significant level of CAT activity was observed in human lung adenocarcinoma (A549-1) cells which had been incubated with a complex of T7 RNA polymerase, pT7-EMC-CAT DNA and DC-chol cationic liposomes. The expression was specific in that T3 RNA polymerase could not replace the T7 RNA polymerase, and that co-delivered T7 RNA polymerase did not enhance the expression of a CAT gene controlled by the SV40 early promoter. The system was optimized in terms of enzyme, DNA and liposome concentrations. Time course experiment indicated that the expression of the T7 system was about 8-10 hours sooner than the SV40 system, consistent with the notion that T7 RNA polymerase does not enter into the nucleus and the transcription takes place in the cytoplasm of the transfected cells. The expression of the T7 system was transient; it declined after 30 hours post transfection, probably due to turnover of the phage enzyme in the mammalian cells. The expression system described here should be useful for gene transfer experiments which require a fast but transient expression of a foreign gene. We have also compared our delivery system with a commercial reagent, Lipofectin, which has been used to deliver T3 or T7 RNA polymerase with a reporter plasmid encoding the T3 or T7 promoter.

Cationic liposomes have provided many advantages over viral vector formulations; however, the problem of inefficient gene expression remains. This is due in part to the nuclear membrane, which limits DNA entry into the nucleus. Cytoplasmic expression systems using T7 RNA polymerase have been developed to express genes in the cytoplasm and avoid the need for nuclear import of DNA. Although these systems show improved transgene expression, little is known about how they function in transfected cells. Direct comparisons between a cytoplasmic and nuclear expression system were carried out with a 293 cell line stably expressing T7 RNA polymerase. A formulation for optimal reporter gene expression was developed and used in conjunction with a variety of subcellular trafficking inhibitors to study the process of DNA endocytosis. Transfected cells were also studied at different stages of the cell cycle to determine the dependence of each system on mitosis. These results showed that cytoplasmic and nuclear expression systems utilize similar endocytosis pathways to the point of endosomal release. Once DNA is released into the cytoplasm, the cytoplasmic expression system shows immediate expression that is proportional to the amount of DNA released. In contrast, DNA targeted for nuclear expression requires additional time for nuclear entry. The level of nuclear expression is also restricted by the limited amount of DNA that is imported into the nucleus. Finally, mitosis is required for effective nuclear expression but not for cytoplasmic expression. Therefore, the cytoplasmic expression system has considerable advantages over traditional nuclear expression systems and may be an effective method for transfecting nondividing cells. Efficient expression of genes delivered by nonviral vectors is hindered owing to poor nuclear transport of plasmid DNA. A potential solution to this problem would be to use a cytoplasmic expression system. Previous studies have shown that this method produces enhanced gene expression when compared with traditional nuclear expression systems; however, the actual mechanisms by which the cytoplasmic expression system works remains unknown. This article focuses on a direct comparison between cytoplasmic and nuclear expression in terms of optimal DNA delivery formulations, intracellular trafficking of DNA, and cell cycle dependence. These results indicate that the cytoplasmic expression system has two primary advantages over nuclear expression in that it does not rely on nuclear DNA transport or mitosis for efficient expression.