Gene transfer into mammalian cells using histone-condensed plasmid DNA

Nuclear localization signal peptides enhance cationic liposome-mediated gene therapy

The use of genes as therapeutic drugs will likely involve non-viral delivery systems. While traditionally less effective for gene expression, the advantages of a non-viral delivery system include ease of production, lower toxicity, and no risk of infection. However, most non-viral systems do not incorporate a mechanism for gene transport into the nucleus. Nuclear localization signal peptides can combine the increased expression of viral delivery systems with the safety and ease of preparation of non-viral delivery systems. A novel non-viral delivery vehicle consisting of a conglomerate of a synthetic nuclear localization signal peptide derived from the SV40 virus, a luciferase encoding PGL3 plasmid, and a cationic lipid DOTAP:DOPE (1:1 w/w) liposome was transfected into SKnSH mammalian neuroblastoma cells. A three-fold increase in luciferase expression was seen with the delivery system containing a NLS peptide over cationic liposome controls. Examination of the factors that limit the rate of transgene expression can potentially lead to the discovery of new ways to improve the efficiency and efficacy of nonviral methods of gene therapy.

Effects of membrane-active agents in gene delivery

A large variety of membrane-modifying agents have been used for the enhancement of DNA(lipo)polycation complex based gene transfer. The magnitude of improvement depends on the nature of the membrane-modifying agent and the (poly)cationic carrier. Within the lipid-free polymer-based systems (polyfection), ligand-polylysine mediated gene transfer can be improved up to more than 1000-fold by pH-specific endosomolytic peptides, glycerol, bacterial proteins or adenovirus particles. Ligand-polyethylenimine or dendrimer-based systems with per se higher efficiency are only slightly (about ten-fold) enhanced by endosomolytic agents. Membrane-active agents show only minor effects when applied to cationic lipid-based gene transfer (lipofection) with DNA complexes formed under optimized conditions using an three- to four-fold excess of positive charges. Less positively charged lipofection complexes can be strongly improved by the addition of membrane-active peptides.

A modular DNA carrier protein based on the structure of diphtheria toxin mediates target cell-specific gene delivery

Modular fusion proteins that combine distinct functions required for cell type-specific uptake and intracellular delivery of DNA present an attractive approach for the development of self-assembling vectors for targeted gene delivery. Here, we describe a novel DNA carrier protein termed GD5 that mimics the structure of the bacterial diphtheria toxin (DT) and facilitates target cell-specific gene transfer via receptor-mediated endocytosis. GD5 carries at the N terminus the DNA-binding domain of the yeast transcription factor Gal4, which is connected to a C-terminal antibody fragment specific for the tumor-associated ErbB2 antigen via an internal DT translocation domain as an endosome escape activity. Bacterially expressed GD5 protein specifically bound to ErbB2-expressing cells and formed protein-DNA complexes with a luciferase reporter gene construct. These complexes, after compensation of excess negative charge with poly-L-lysine, served as a specific transfection vector for ErbB2-expressing cells. Inhibitors of endosomal acidification drastically reduced GD5-mediated transfection, indicating that the DT translocation domain of GD5, similar to the parental toxin, is strictly dependent on the transit through an acidic environment. Our results suggest that fusion proteins that employ the natural endosome escape mechanism of bacterial toxins might aid in the development of efficient nonviral vectors for applications in gene therapy.

Polylysine-based transfection systems utilizing receptor-mediated delivery

Receptor-mediated gene transfer is a promising gene delivery technique. It employs a DNA-binding polycation, such as polylysine, to compact plasmid DNA to a size that can be taken up by cells (<100-200 nm). To allow internalization by receptor-mediated endocytosis, cell binding ligands, such as asialoglycoproteins or galactose for hepatocytes, anti-CD3 and anti-CD5 for T-cells, and transferrin, have been covalently attached to polylysine. Intracellular barriers for successful gene transfer include release of DNA complexes from endosomes or lysosomes, nuclear import of DNA complexes, and disassembly of the DNA-polylysine particles. Release of particles from internal vesicles has been achieved by the addition of lysosomotropic agents or glycerol to the transfection medium, or by the incorporation of endosomolytic compounds, such as viruses or membrane active peptides. This technique has already been used to transfect certain organs in vivo, including liver and lung.

In vitro gene transfer using human papillomavirus-like particles

Recombinant papillomavirus-like particles have recently been shown to be highly effective for the prevention of papillomavirus infections and associated tumors, and a virus-like particle-based vaccine against the most prevalent HPV causing genital infection in humans will be developed in the near future. Another use of these virus-like particles may lie in gene therapy and DNA immunization. We report here that human papillomavirus-like particles composed of the major capsid protein (L1) of HPV-16 are able to package unrelated plasmid DNA in vitro and then to deliver this foreign DNA to eukaryotic cells with the subsequent expression of the encoded gene. The results indicate higher gene transfer than with DNA alone or with liposome. Virus-like particles are a very promising vehicle for delivering genetic material into target cells. Moreover, the preparation of the gene transfer vehicle is relatively easy.

A combinatorial approach to the discovery of efficient cationic peptoid reagents for gene delivery

A family of N-substituted glycine oligomers (peptoids) of defined length and sequence are shown to condense plasmid DNA into small particles, protect it from nuclease degradation, and efficiently mediate the transfection of several cell lines. The oligomers were discovered by screening a combinatorial library of cationic peptoids that varied in length, density of charge, side-chain shape, and hydrophobicity. Transfection activity and peptoid-DNA complex formation are shown to be highly dependent on the peptoid structure. The most active peptoid is a 36-mer that contains 12 cationic aminoethyl side chains. This molecule can be synthesized efficiently from readily available building blocks. The peptoid condenses plasmid DNA into uniform particles 50-100 nm in diameter and mediates the transfection of a number of cell lines with efficiencies greater than or comparable to DMRIE-C, Lipofectin, and Lipofectamine. Unlike many cationic lipids, peptoids are capable of working in the presence of serum.

Acid nuclear extracts as mediators of gene transfer and expression

In an attempt to demonstrate transfection-active DNA packaging proteins in the cell nucleus, we prepared acid nuclear extracts with perchloric acid and subsequent protein fractions by stepwise acetone precipitation. The original extract and these fractions containing different compositions of nuclear proteins were used as DNA packaging agents. After the formation of complexes between these protein fractions and reporter genes, the addition of these complexes to the cells resulted in high transfection rates. Gel electrophoresis shows that the most active fractions contain histone H1 and HMG17. HMG1 exhibits a smaller activity. This result was confirmed by positive transfection experiments with commercial histone H1. Our results show that the transfection activity of acid nuclear protein fractions and histone H1 is dependent on the presence of calcium.

DNA vector chemistry: the covalent attachment of signal peptides to plasmid DNA

The nuclear entry of exogenous DNA in mammalian cells is critical for efficient gene transfer. A novel technique was developed for the covalent attachment of cationic peptides to double-stranded DNA using a cyclo-propapyrroloindole cross-linker. The attachment of the SV40 large T antigen nuclear localization signal peptide induced the nuclear accumulation of the conjugated DNA in digitonin-permeabilized cells via the classical pathway for the nuclear transport of karyophilic proteins. Increased nuclear uptake of the modified DNA, however, did not occur after it was microinjected into the cytoplasm of cultured cells. This demonstration that the covalent modification of DNA with a signal peptide alters its behavior and interaction with other cellular factors portends the potential of DNA vector chemistry to enhance the efficiency of cellular gene transfer.

Transfection by cationic liposomes using simultaneous single cell measurements of plasmid delivery and transgene expression

Cationic liposomes are potentially important gene transfer vehicles, although their application has been limited by relatively low efficiency of transgene expression. Single cell quantitative methods, such as those used in this study, should permit a more detailed understanding of the relationships between delivered plasmid and transgene expression. Intracellular plasmid delivery and transgene expression were measured simultaneously using photoconjugated ethidium monoazide as an intracellular plasmid delivery marker and green fluorescent protein (GFP(S65T)) as a transgene expression marker. Quantitative flow cytometry was used to estimate plasmid copy number and GFP(S65T) molecules in single cells. The plasmid was delivered to HeLa cells with a cationic liposome vehicle containing 1,2-dioleoyloxy-3-trimethylammonium-propane and dioleoylphosphatidylethanolamine (1:1 mol/mol). Treatment was carried out continuously for 24 h. Flow cytometry measurements on 20, 000 cells were performed during treatment and for 48 h post-treatment. On a single cell basis, transgene expression efficiency and average GFP(S65T) expression level increased with intracellular plasmid copy number. After 3-h exposure to the liposomal vector, more than 95% of the cells were positive for plasmid entry, but none had detectable transgene expression. Maximum transgene expression was achieved at 24 h and remained unchanged at the 72-h measurement. At 24 h, the average positive cell contained 1.6 x 10(5) plasmid copies and 2.3 x 10(6) GFP(S65T) molecules. Importantly, the measurement strategies revealed that transgene expression varied widely within the entire cell population. Although only 30% of all cells expressed transgene, the subpopulation of cells that rapidly incorporated the vector demonstrated 100% efficiency in transgene expression. This study identifies parameters that modulate highly efficient transgene expression from plasmid delivery by cationic liposomes.

Gene transfer using a novel fusion protein, GAL4/invasin

The delivery of DNA to target cells using simple, defined, nonviral systems has become an area of intense interest in gene therapy. We describe here the development and characterization of one such novel system. A recombinant, bifunctional, fusion protein was expressed and purified from Escherichia coli. This protein consists of the DNA-binding domain of the yeast transcription factor GAL4 fused to the cell binding, internalization domain of the Yersinia pseudotuberculosis inv gene product, invasin. This protein, GAL4/Inv, together with poly-L-lysine, formed complexes with a chloramphenicol acetyltransferase (CAT) reporter plasmid that contains eight repeats of the GAL4 consensus recognition sequence. These complexes were shown to transfect target cells in an invasin receptor-dependent manner, resulting in transient CAT expression. A simple, targeted DNA delivery vehicle, as we describe here, represents a viable approach to nonviral gene delivery.

Intracavitary liposome-mediated p53 gene transfer into glioblastoma with endogenous wild-type p53 in vivo results in tumor suppression and long-term survival

A cavitary glioblastoma model was created by injection of RT-2 cells, which express endogenous wild type p53, into the peritoneal cavity of nude mice. This model developed multiple layers of tumor cells invading the peritoneal surface and was used to mimic the postoperative surgical cavity remaining after glioblastoma (GBM) excision in patients. Rhodamine labeled DMRIE/DOPE + DNA complexes were found to penetrate at least 20 tumor cell layers. Injection of p53 gene/liposome complexes into the intraperitoneal cavity after the tumor was established resulted in massive tumor necrosis. Prominent staining of human p53 protein using the DO-1 antibody was found in tumor cells near the necrotic lesions. Tumor explants expressed human p53 protein and showed a 54% growth reduction in an in vitro growth assay. Further, DMRIE/DOPE mediated p53 gene transfection significantly increased the mean survival time of tumor bearing mice compared to vector control. These results demonstrate the efficiency of using exogenous wild type p53 to suppress glioblastoma cell with endogenous wild type p53 in vivo through liposome mediated transfection method.