New structures in complex formation between DNA and cationic liposomes visualized by freeze-fracture electron microscopy.

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.

DC-Chol liposome-mediated gene transfer in rat spinal cord.

We examined the potential of non-viral vector-mediated gene transfection in the rat spinal cord. Reporter gene (beta-gal) or brain-derived neurotrophic factor (BDNF) cDNA containing a pCMV promoter complexed with DC-Chol liposomes was injected into the intact rat spinal cord gray matter. RT-PCR confirmed the increased expression of BDNF mRNA in the injection areas. X-gal staining demonstrated the localized expression of beta-gal reporter genes. No overt tissue damage caused by DC-Chol liposome/DNA complex injections was detected. These results suggest that cationic liposome-mediated delivery can be a practical method for gene transfer in spinal cord.

Developing non-viral DNA delivery systems for cancer and infectious disease.

Efforts to deliver therapeutic genes are frequently rebuffed by the body's adaptive immune response against viral delivery vectors. Attempts to circumvent this problem using non-viral delivery systems have encountered problems with transient expression and inflammatory responses induced by reaction of the innate immune system reacting against bacterial DNA. However, within the past decade, these barriers to non-viral DNA delivery have been recognized as potential allies in the development of novel vaccines for cancer and infectious disease. This review summarizes preclinical and current clinical studies testing the formulation, delivery route and adjuvant options in the development of novel DNA-based vaccines.

Protamine sulfate enhances lipid-mediated gene transfer.

A polycationic peptide, protamine sulfate, USP, has been shown to be able to condense plasmid DNA efficiently for delivery into several different types of cells in vitro by several different types of cationic liposomes. The monovalent cationic liposomal formulations (DC-Chol and lipofectin) exhibited increased transfection activities comparable to that seen with the multivalent cationic liposome formulation, lipofectamine. This suggests that lipofectamine's superior in vitro activity arises from its ability to condense DNA efficiently and that protamine's primary role is that of a condensation agent, although it also possesses several amino acid sequences resembling that of a nuclear localization signal. While the use of polycations to condense DNA has been previously reported, the of protamine sulfate, USP as a condensation agent was found to be superior to poly-L-lysine as well as to various other types of protamine. These differences among various salt forms of protamine appear to be attributable to structural differences between the protamines and not due to differences in the net charge of the molecule. The appearance of lysine residues within the protamine molecule correlate with a reduction in binding affinity to plasmid DNA as well as an observed loss in transfection enhancing activity. This finding sheds light on the structural requirements of condensation agents for use in gene transfer protocols. Furthermore, protamine sulfate, USP is an FDA-approved compound with a documented safety profile and could be readily used as an adjuvant to a human gene therapy protocol.

The effect of cationic liposome pretreatment and centrifugation on retrovirus-mediated gene transfer.

Pretreatment of retroviral supernatants with the cationic liposomes DOTMA-DOPE (Lipofectin), DC-Chol-DOPE and DOSPA-DOPE (Lipofectamine) was found to enhance static transductions of TF-1 target cells. The relative effectiveness at increasing transduction efficiencies (TE) was: DOSPA > DC-Chol > DOTMA, resulting in average increases over nontreated controls of 11.9-, 6.2- and 1.2-fold, respectively. This pretreatment was found to be synergistic when combined with centrifugation, having the same order of effectiveness, and resulting in 57-, 35- and 27-fold increases over nontreated controls. For Lipofectamine and DC-Chol-DOPE liposomes, the combined approach yielded 2.2- and 1.3-fold increases over untreated centrifuged samples. Individual colonies picked from colony-forming unit granulocyte-macrophage assays of infected CD34+ cells were screened for the presence of the transgene by polymerase chain reaction (PCR). Colonies from cells infected using centrifugation were positive 27% of the time, while the combined approach had positive colonies 31 and 50% of the time for DC-Chol and Lipofectamine, respectively. The addition of protamine sulfate to the liposome-supernatant mixture during pretreatment was found to be inhibitory. With increasing centrifugal force, the TE of cells infected with Lipofectamine pretreated and untreated supernatants increased proportionally. However, the TE of the cells infected with the pretreated supernatants was significantly higher than the TE of the cells infected with untreated supernatants at all points examined. The increase in TE associated with liposomal pretreatment of retroviral supernatants was not shown to be attributed to a nonreceptor-mediated pathway for viral entry into the cell.

Repeat administration of DNA/liposomes to the nasal epithelium of patients with cystic fibrosis.

The major cause of mortality in patients with cystic fibrosis (CF) is lung disease. Expression of the cystic fibrosis transmembrane conductance regulator (CFTR) gene product in the airways is a potential treatment. Clinical studies in which the CFTR cDNA was delivered to the respiratory epithelia of CF patients have resulted in modest, transient gene expression. It seems likely that repeated administration of the gene transfer vector will be required for long-term gene expression. We have undertaken a double-blinded study in which multiple doses of a DNA/liposome formulation were delivered to the nasal epithelium of CF patients. Ten subjects received plasmid DNA expressing the CFTR cDNA complexed with DC-Chol/DOPE cationic liposomes, whilst two subjects received placebo. Each subject received three doses, administered 4 weeks apart. There was no evidence of inflammation, toxicity or an immune response towards the DNA/liposomes or the expressed CFTR. Nasal epithelial cells were collected 4 days after each dose for a series of efficacy assays including quantitation of vector-specific DNA and mRNA, immunohistochemistry of CFTR protein, bacterial adherence, and detection of halide efflux ex vivo. Airway ion transport was also assessed in vivo by repeated nasal potential difference (PD) measurements. On average, six of the treated subjects were positive for CFTR gene transfer after each dose. All subjects positive for CFTR function were also positive for plasmid DNA, plasmid-derived mRNA and CFTR protein. The efficacy measures suggest that unlike high doses of recombinant adenoviral vectors, DNA/liposomes can be successfully re-administered without apparent loss of efficacy.