Optimization of cationic lipid mediated gene transfer: structure-function,physico-chemical,and cellular studies

The rationale design aimed at the enhancement of cationic lipid mediated gene transfer is discussed. These improvements are based on the straight evaluation of the structure-activity relationship and on the introduction of new structures. Much attention have been given to the supramolecular structures of the lipid/DNA complexes, to the effect of serum on gene transfer and to the intracellular trafficking of the lipoplexes. Finally new avenue using reducible cationic lipids has been discussed.     

Protamine Sulfate Provides Enhanced and Reproducible Intravenous Gene Transfer by Cationic Liposome/DNA Complex

Abstract

A novel lipid/polycation/DNA (LPD) formulation has been developed for in vivo gene transfer. It involves the condensation of plasmid DNA with protamine sulfate, a cationic polypeptide, followed by the addition of DOTAP cationic liposomes. Compared with DOTAP/DNA complex, LPD offers greater protection of plasmid DNA against enzymatic digestion and gives consistently higher gene expression in mice via tail vein injection. The in vivo efficiency of LPD was dependent upon charge ratio and was also affected by the lipid used. Increasing the amount of DNA delivered induced an increase in gene expression. The optimal dose was approximately 50 μg per mouse, at which concentration approximately 10 ng luciferase protein per mg extracted tissue protein could be detected in the lung. Gene expression in the lung was detected as early as 1 h after injection, peaked at 6 h, and declined thereafter. Using LacZ as a reporter gene, it was shown that endothelial cells were the primary locus of transgene expression in both lung and spleen. No sign of inflammation in these organs was noticed. Since protamine sulfate has been proven to be non-toxic and only weakly immunogenic in humans, this novel vector may be useful for the clinical use of gene therapy.     

Cationic Liposomes Containing Disulfide Bonds in Delivery of Plasmid DNA

Abstract

Cationic liposomes are non-viral gene transfer vectors for in vitro and in vivo experiments. In the present studies, we investigated whether a disulfide linkage in a cationic lipid was reducible by cell lysate resulting in the release of plasmid DNA and enhanced gene transfection. We also investigated if the differences in transgene production were from differences in total amount of cellular associated plasmid DNA. We systematically compared the gene transfection of disulfide bond containing-cationic lipid, 1', 2'-dioleoyl-sn-glycero-3'-succinyl-2-hydroxyethyl disulfide ornithine conjugate (DOGSDSO), its non-disulfide-containing analog, 1', 2'-dioleyl-sn-glycero-3'-succinyl-1, 6-hexanediol ornithine conjugate (DOGSHDO), 1, 2-dioleoyl-3-trimethylammonium-propane (DOTAP). Two transgene reporter systems (i.e., luciferase and green fluorescent protein (GFP)) were used to address transgene transgene expression and transgene efficiency. Experiments with the luciferase expression plasmid resulted in transgene activity up to 11 times greater transgene production for the disulfide containing lipid in at least two different cell lines, COS 1 and CHO cells. When transgene expression was determined by GFP activity, DOGSDSO liposomes were four times greater than the non-disulfide lipid or positive control (DOTAP) liposomes. By quantifying nucleic acid uptake by flow cytometry it was also demonstrated that increase expression was not solely from an increase in cellular plasmid DNA accumulation. These results demonstrate that cationic lipids containing a disulfide linkage are a promising method for gene transfer.     

Novel Cationic Phosphonolipids Agents for in Vitro Gene Transfer to Epithelial Cell Lines

Abstract

The use of cationic liposomes is one of the main approaches currently investigated to introduce into a cell a gene with therapeutic properties. This study presents in vitro results obtained with a new family of gene transfer agents, the phosphonolipids. We have synthesized 37 members of this family and optimized the conditions of in vitro gene transfer targeted at a lung epithelial cell line (CFT1 cells) by using a reporter gene (β-galactosidase). Two quantitative tests, a CPRG¹ (Chlorophenol red galactopyranoside) test and a Flow cytometric assay (FACS-Gal¹ assay), have been used to determine the percentage of transfected cells. The cationic phosphonolipids were tested alone or formulated with 50% DOPE¹ (Dioleoylphosphatidylethanolamine) (w:w). The results obtained with the CPRG test led us to select 7 compounds that were more efficient than the commercialized lipids Lipofectin, Lipofectamine and Transfectam. The transfer kinetics of the transgene were studied and showed that more than 20 % of cells were still positive at day 7 after transfection.     

Cationic Liposome-Mediated Gene Delivery Via Systemic Administration

Abstract

Cationic liposomes have been studied as a potential carrier for delivering genes to cells for the purpose of gene therapy. This report summarizes our efforts to characterize the in vivo expression of transgene delivered by cationic liposomes via intravenous administrtion. Using a CMV driven gene expression system containing cDNA of luciferase or green fluorescence protein gene as a reporter and two commonly used cationic lipids, 2, 3-dioleoyloxypropyl-1-trimethyl ammonium chloride (DOTMA) and 2, 3-dioleoyloxyl-1-trimethylammonium propanyl chloride (DOTAP), we demonstrate that a significant level of gene expression can be obtained in different organs including the lung, heart, spleen, liver and kidneys following intravenous administration in the mouse. Our finding show that the transfection efficiency of cationic liposomes is determined by the structure of the cationic lipids, the lipid composition of liposomes and cationic lipid to DNA ratio. Furthermore, gene expression was short in duration, peaked between 4-24 hours post injection, and dropped to less than 1% of the peak level within a 4 day period. Experiments with repeated injections revealed that cells initially transfected by the first transfection were not fully responsive to the subsequent second transfection for approximately 14 days.     

Morphology of Cationic Liposome/DNA Complexes in Relation to Their Chemical Composition

Abstract

Electron microscopy is used to show the morphology of liposome/DNA complexes as related to their cationic component, the molar ratio of the helper lipid (usually DOPE¹), the nature of the DNA-component, as well as the composition of the media. Liposomes made of monovalent cationic amphiphiles adhere and fuse during interaction with negatively charged DNA thereby complexing the DNA. The size of the resulting complexes is depending upon charge neutralization and is smallest at a slightly positive net charge. At molar ratios of DOPE, to the cationic component of ≥ 1.5, hexagonal lipid tubules are formed, especially in media containing high salt concentrations, and even in the control lipid mixture, not interacting with any DNA or oligonucleotide. Complexes, made of plasmid-DNA, monovalent cationic amphiphiles, and DOPE at a lower molar ratio, show additionally to the semifused or fused liposomes a new structure, called spaghetti-like structure, representing a bilayer-coated, supercoiled DNA. Single-strand and short oligonucleotides seem not to form such structures during interaction with monovalent cationic liposomes. Neither fusion nor spaghetti formation is observed during interaction of DNA with liposomes made of polyvalent cationic amphiphiles. In general, small complexes consisting of some few semifused liposomes bearing the self-encapsulated nucleic acid and additionally the spaghetti-like structure, free or connected with these complexes, seem to be candidates for the transfectionactive structure rather than large extended H_II¹-lipid arrangements.     

Lipid-Free Antigen B Subunits from Echinococcus granulosus: Oligomerization,Ligand Binding,and Membrane Interaction Properties

BackgroundThe hydatid disease parasite Echinococcus granulosus has a restricted lipid metabolism, and needs to harvest essential lipids from the host. Antigen B (EgAgB), an abundant lipoprotein of the larval stage (hydatid cyst), is thought to be important in lipid storage and transport. It contains a wide variety of lipid classes, from highly hydrophobic compounds to phospholipids. Its protein component belongs to the cestode-specific Hydrophobic Ligand Binding Protein family, which includes five 8-kDa isoforms encoded by a multigene family (EgAgB1-EgAgB5). How lipid and protein components are assembled into EgAgB particles remains unknown. EgAgB apolipoproteins self-associate into large oligomers, but the functional contribution of lipids to oligomerization is uncertain. Furthermore, binding of fatty acids to some EgAgB subunits has been reported, but their ability to bind other lipids and transfer them to acceptor membranes has not been studied.Conclusions/SignificanceWe show that EgAgB apolipoproteins can oligomerize in the absence of lipids, and can bind and transfer fatty acids to phospholipid membranes. Since imported fatty acids are essential for Echinococcus granulosus, these findings provide a mechanism whereby EgAgB could engage in lipid acquisition and/or transport between parasite tissues. These results may therefore indicate vulnerabilities open to targeting by new types of drugs for hydatidosis therapy.     

Use of Cationic Lipids to Enhance the Biological Activity of Antisense Oligonucleotides

Abstract

Antisense oligonucleotides bind to specific mRNA or pre-mRNA sequences through Watson-Crick base pairing, resulting in decreased expression of the targeted protein. The use of cationic lipids to enhance cellular uptake of antisense oligonucleotides is reviewed herein. Cationic lipids such as N[1-(2,3-dioleyloxy)propyl]-N, N, N-trimethylammonium chloride (DOTMA) were found to enhance the biological activity of phosphorothioate oligonucleotides by at least 1000-fold in cell culture. Cationic lipid preparations enhanced both the rate and amount of oligonucleotide which associated with cells. In addition, DOTMA markedly changed the subcellular distribution of the oligonucleotide. In the absence of lipid, fluorescein labelled phosphorothioate oligonucleotides accumulated in discrete cytoplasmic structures. In the presence of cationic lipids, the oligonucleotides concentrated within the nucleus, were excluded from nucleoli, and localized in punctate cytoplasmic structures. The accumulation of the oligonucleotide in the nucleus was inhibited by incubation of the cells at 4°C and by monensin, but not by chloroquine, ammonium chloride, or nocodazole. Cell lines, both primary and transformed, differ markedly in their sensitivity to inhibition of gene expression with antisense oligonucleotides in the presence of cationic lipids. The differential sensitivity of the cells correlates with the amount of ³⁵S-labelled oligonucleotide associated with the cells and the number of cells in the population which take up the oligonucleotide. Our studies have demonstrated that several types of cationic lipids markedly enhance the activity of phosphorothioate oligonucleotides in cell culture models. We are currently investigating the ability of cationic lipids to enhance activity of antisense oligonucleotides in more complex systems such as organ cultures and in animals.     

Induction of alloreactive cytotoxic T lymphocytes by intra-splenic immunization with allogeneic class I Major Histocompatibility Complex DNA and DC-chol cationic liposomes

Abstract

A simple strategy for designing a cancer immunotherapeutic system involves modification of tumor cells from tumor-bearing animals in vivo in such a way that the host can evoke a specific immune response against them. We have expressed allogeneic class I major histocompatibility complex (MHC) molecules on tumor cells, through ex vivo DNA-mediated gene transfer. These molecules are potent immuno-modulators for the stimulation of strong immune reactions against certain malignancies. In order to achieve efficient gene delivery to tumor cells in vivo we have compared the efficiencies of gene transfer into mammalian tumor cells by the biolistic particle delivery system and cationic liposomes. In this report, we have demonstrated that cationic liposomes prepared by DC-chol and DOPE gives the best efficiency of transfection for tumor cells in vivo. We also showed that a strong anti-H-2K^b allo-reactive cytotoxic T lymphocyte (CTL) response could be generated following in vivo immunization of AKR/J mouse spleens with the H-2K^b gene and DC-chol cationic liposomes. The direct immunization of mouse spleens to induce cell-mediated immunity against exogenous antigens may allow alternative treatment strategies for cancer immunotherapy.     

Transfection with fluorinated lipoplexes based on fluorinated analogues of DOTMA, DMRIE and DPPES

Fluorinated double-chain (poly)cationic lipids (one or both of these chains being ended by a highly fluorinated tail) which are close analogues of DOTMA, DMRIE or DPPES were designed as synthetic vectors for gene delivery. For N/P ratios (N=number of amine functions of the lipid; P=number of DNA phosphates) from 0.8 to 5, these fluorinated cationic lipids condensed DNA, with or without the use of DOPE, to form fluorinated lipoplexes. No specific cell toxicity was evidenced for these new fluorinated lipoplexes. The efficiency of some of the fluorinated lipoplexes to transfect lung epithelial A549 cells was comparable to that of the first generation of fluorinated lipoplexes made from fluorinated analogues of DOGS (Transfectam) [Bioconjug. Chem. 12 (2001) 114]. These results, combined with the higher in vivo transfection potential found for fluorinated lipoplexes than for conventional lipoplexes or PEI polyplexes [J. Gene Med. 3 (2001) 109], confirm that fluorinated lipoplexes are very promising gene transfer systems.     

How are Nucleic Acids Released in Cells from Cationic Lipid-Nucleic Acid Complexes?

Abstract

Cationic lipid-nucleic acid complexes are widely used to deliver oligonucleotides, RNA and DNA into cells. Although much has been learned about the structure and forces that hold the complex together, an understanding of the mechanism of release of the nucleic acids from the complex into cells has been lacking. Recent studies have shown that anionic liposomes with compositions similar to the cytoplasmic face of the endosomal membrane are potent agents for inducing the rapid release of oligonucleotides and DNA from cationic lipid-nucleic acid complexes. Based upon these results, we propose that after the cationic lipid/nucleic complex is internalized by endocytosis it destabilizes the endosomal membrane. This destabilization induces flip-flop of anionic lipids from the cytoplasmic facing monolayer, which laterally diffuse into the complex and form a charge neutral ion-pair with the cationic lipids. This results in displacement of the nucleic acid from the cationic lipid and subsequent release of the nucleic acid into cytoplasm of the cell. We review the data that show the proposed mechanism accounts for a variety of observations on cationic lipid/nucleic acid complex-cell interactions.     

FACTORS INFLUENCING THE EFFICIENCY OF LIPOPLEXES MEDIATED GENE TRANSFER IN LUNG AFTER INTRAVENOUS ADMINISTRATION*

The objectives of this study were to test the influence of different parameters on the in vivo cationic lipid mediated gene transfer in lung after intravenous administration. Luciferase activity was evaluated in lung tissue 24 hours after intravenous administration of different types of lipoplexes. These included lipoplexes prepared using cationic phosphonolipids or DOTAP and various amounts of plasmid DNA. Using two different plasmids we tested the influence of plasmid size on transfection efficiency in vivo. In a last series of experiments, lipoplexes were prepared using different excipients (water, NaCl or 5% glucose solution) and three injection volumes were tested. We demonstrate that chemical structure modifications such as cation substitution and increment of the aliphatic chain length significantly improve transfection efficiency. High luciferase levels are obtained by increasing lipid to DNA charge ratio and plasmid DNA dose and decreasing plasmid size. Lipoplexes prepared in physiological NaCl solution and injected using a volume of 800μl are significantly the most effective.

Cationic lipid mediated gene transfer in lung tissue after intravenous administration is influenced by factors including cationic lipid chemical structure, lipid to DNA ratio and plasmid dose. Nevertheless, plasmid size, injection volume and the excipient, used for the lipoplexes preparation, are also important factors and must be considered for an optimization of in vivo gene delivery using intravenous administration.     

Novel carbamate-linked quaternary ammonium lipids containing unsaturated hydrophobic chains for gene delivery

In this paper, two novel carbamate-linked quaternary ammonium lipids (MU18: a lipid with a mono-ammonium head; GU18: a lipid with a Gemini-ammonium head) containing unsaturated hydrophobic chains were designed and synthesized. The chemical structures of the synthetic lipids were characterized by infrared spectrum, ESI-MS, ¹H NMR, ¹³C NMR, and HPLC. For investigating the effect of unsaturation on gene delivery, the previous reported saturated cationic liposomes (MS18 and GS18) were used as comparison. Cationic liposomes were prepared by using these cationic lipids and neutral lipid DOPE at the molar ratio of 1:1. Particle sizes and zeta potentials of the cationic liposomes were studied to show that they were suitable for gene transfection. The binding abilities of the cationic liposomes were investigated by gel electrophoresis at various N/P ratios from 0.5/1 to 8/1. The results indicated that the binding ability of GU18 was much better than MU18 and the saturated cationic liposomes (MS18 and GS18). DNA transfection of these liposomes comparable to commercially available reagent (DOTAP) was achieved in vitro against Hela, HepG-2 and NCI-H460 cell lines. GU18 showed higher transfection at the N/P ratio of 3/1 than other cationic liposomes and the positive control, DOTAP. All of the liposomes presented a relatively low cytotoxicity, which was measured by MTT. Therefore, the synthetic lipids bearing unsaturated hydrophobic chains and Gemini-head could be promising candidates for gene delivery.     

Enhanced Gene Delivery and Expression in Human Hepatocellular Carcinoma Cells by Cationic Immunoliposomes

Abstract

A targeted vector allowing enhanced gene transfer to human hepatocellular carcinoma (HCC¹) cells in vitro was developed using cationic liposomes covalently conjugated with the mAb AF-20. This high affinity antibody recognizes a rapidly internalized 180 kDa cell surface glycoprotein which is abundantly expressed on the surface of human HCC and other cancer cells. Quantitative binding analysis of liposomes with target cells by flow cytometry showed specific association of mAb-targeted liposomes with human HCC cells. Using mAb-targeted cationic liposomes containing 20% DOTAP, in the presence or absence of serum, gene expression in HuH-7 cells was enhanced up to 40-fold as compared to liposomes conjugated with an isotype-matched non-relevant control antibody. Transfection specificity was not observed in a control cell line that does not express the antigen recognized by mAb AF-20. This study demonstrates that cationic liposome formulations can be targeted with monoclonal antibodies (mAbs) to enhance specific in vitro gene delivery and expression in the presence or absence of serum.     

Aminoglycoside-derived cationic lipids as efficient vectors for gene transfection in vitro and in vivo

Background

Cationic lipids are at present very actively investigated for gene transfer studies and gene therapy applications. Basically, they rely on the formation of DNA/lipid aggregates via electrostatic interactions between their cationic headgroup and the negatively charged DNA. Although their structure/activity relationships are not well understood, it is generally agreed that the nature of the positive headgroup impacts on their transfection activity. Thus, we have directed our efforts toward the development of cationic lipids with novel cationic moieties. In the present work, we have explored the transfection potential of the lipophilic derivatives of the aminoglycoside kanamycin A. Indeed, aminoglycosides, which are natural polyamines known to bind to nucleic acids, provide a favorable scaffold for the synthesis of a variety of cationic lipids because of their structural features and multifunctional nature.

Methods and results

We report here the synthesis of a cationic cholesterol derivative characterized by a kanamycin A headgroup and of its polyguanidinylated derivative. The amino‐sugar‐based cationic lipid is highly efficient for gene transfection into a variety of mammalian cell lines when used either alone or as a liposomal formulation with the neutral phospholipid dioleoylphosphatidylethanolamine (DOPE). Its polyguanidinylated derivative was also found to mediate in vitro gene transfection. In addition, colloidally stable kanamycin‐cholesterol/DOPE lipoplexes were found to be efficient for gene transfection into the mouse airways in vivo.

Conclusions

These results reveal the usefulness of cationic lipids characterized by headgroups composed of an aminoglycoside or its guanidinylated derivative for gene transfection in vitro and in vivo. Copyright © 2002 John Wiley & Sons, Ltd.

     

Example of fatty acid-loaded lipoplex in enhancing in vitro gene transfer efficacies of cationic amphiphile

Herein, we report on the design and synthesis of a novel nontoxic cationic amphiphile N,N-di-n-tetradecyl-N-[2-[N',N'-bis(2-hydroxyethyl)amino]ethyl]-N-(2-hydroxyethyl)ammonium chloride (lipid 1) whose in vitro gene transfer efficacies in CHO, COS-1, MCF-7, and HepG2 cells are remarkably enhanced when used in combination with 30 mole percent added myristic acid. Reporter gene expression assay using p-CMV-SPORT-beta-gal reporter gene revealed poor gene transfer properties of the cationic liposomes of lipid 1 and cholesterol (colipid). However, the in vitro gene delivery efficacies of lipid 1 were found to be remarkably enhanced when the cationic liposomes of lipid 1 and cholesterol were prepared in the presence of 30 mole percent added myristic acid (with respect to lipid 1) as the third liposomal ingredient. The whole cell histochemical X-gal staining of representative CHO cells further confirmed the significantly enhanced gene transfer properties of the fatty acid-loaded cationic liposomes of lipid 1 and cholesterol. Electrophoretic gel patterns in the gel mobility shift assay supports the notion that better DNA release from fatty acid lipoplexes might play a role in their enhanced gene transfer properties. In addition, such myristic acid-loaded lipoplexes of lipid 1 were also found to be serum-compatible up to 30% added serum. Taken together, our present findings demonstrate that the transfection efficacies of fatty acid-loaded lipoplexes are worth evaluating particularly when traditional cationic liposomes prepared with either cholesterol or DOPE colipids fail to transfect cultured cells.     

Simple preparation and characterization of cationic liposomes associated with a monoclonal antibody against glioma-associated antigen (immunoliposomes)

Abstract

In this study we prepared and characterized monoclonal antibody associated cationic liposomes (immunoliposomes) to be used as a vehicle for human gene therapy of malignant glioma. This association method is especially amenable to mass production. The immunoliposomes consist of N-(a-trimethylammonio-acetyl)-didodecyl-D-glutamate chloride (TMAG), dilauroyl phosphatidylcholine (DLPC), and dioleoyl phosphatidyl- ethanolamine (DOPE) in a molar ratio of 1:2:2 as TMAG:DLPC:DOPE. Their preparation required only the addition of a solution containing plasmid DNA and a monoclonal antibody against glioma-associated antigen to a lipid film of the above three lipids. The association of antibody on the surface of immunoliposomes was confirmed by an immunochemical procedure. Liposome-mediated LacZ gene transfection of human glioma cells resulted in p-galactosidase activity about 2- to 3-fold higher when immunoliposomes were used as compared to control liposomes that were not associated to antibody. Also, the production of human (3-interferon (HuIFN-P) into the medium was 2- to 7-fold higher when HuIFN-P gene was transfected. Based on the present results, the immunoliposomes associating a monoclonal antibody against glioma-associated antigen may become effective carriers for gene transfer to human glioma cells.     

‘Click’ synthesized sterol-based cationic lipids as gene carriers,and the effect of skeletons and headgroups on gene delivery

In this work, we have successfully prepared a series of new sterol-based cationic lipids (1–4) via an efficient ‘Click’ chemistry approach. The pDNA binding affinity of these lipids was examined by EB displacement and agarose-gel retardant assay. The average particle sizes and surface charges of the sterol-based cationic lipids/pDNA lipoplexes were analyzed by dynamic laser light scattering instrument (DLS), and the morphologies of the lipoplexes were observed by atomic force microscopy (AFM). The cytotoxicity of the lipids were examined by MTT and LDH assay, and the gene transfection efficiencies of these lipid carriers were investigated by luciferase gene transfection assay in various cell lines. In addition, the intracellular uptake and trafficking/localization behavior of the Cy3-DNA loaded lipoplexes were preliminarily studied by fluorescence microscopy. The results demonstrated that the pDNA loading capacity, lipoplex particle size, zeta potential and morphology of the sterol lipids/pDNA lipoplexes depended largely on the molecular structure factors including sterol-skeletons and headgroups. Furthermore, the sterol-based lipids showed quite different cytotoxicity and gene transfection efficacy in A549 and HeLa cells. Interestingly, it was found that the cholesterol-bearing lipids 1 and 2 showed 7–10⁴ times higher transfection capability than their lithocholate-bearing counterparts 3 and 4 in A549 and HeLa cell lines, suggested that the gene transfection capacity strongly relied on the structure of sterol skeletons. Moreover, the study on the structure–activity relationships of these sterol-based cationic lipid gene carriers provided a possible approach for developing low cytotoxic and high efficient lipid gene carriers by selecting suitable sterol hydrophobes and cationic headgroups.     

Phase diagram, stability, and overcharging of lamellar cationic lipid-DNA self-assembled complexes.

Cationic lipid-DNA (CL-DNA) complexes comprise a promising new class of synthetic nonviral gene delivery systems. When positively charged, they attach to the anionic cell surface and transfer DNA into the cell cytoplasm. We report a comprehensive x-ray diffraction study of the lamellar CL-DNA self-assemblies as a function of lipid composition and lipid/DNA ratio, aimed at elucidating the interactions determining their structure, charge, and thermodynamic stability. The driving force for the formation of charge-neutral complexes is the release of DNA and lipid counterions. Negatively charged complexes have a higher DNA packing density than isoelectric complexes, whereas positively charged ones have a lower packing density. This indicates that the overcharging of the complex away from its isoelectric point is caused by changes of the bulk structure with absorption of excess DNA or cationic lipid. The degree of overcharging is dependent on the membrane charge density, which is controlled by the ratio of neutral to cationic lipid in the bilayers. Importantly, overcharged complexes are observed to move toward their isoelectric charge-neutral point at higher concentration of salt co-ions, with positively overcharged complexes expelling cationic lipid and negatively overcharged complexes expelling DNA. Our observations should apply universally to the formation and structure of self-assemblies between oppositely charged macromolecules.     

Liposome Mediated Transfer of Marker and Cytokine Genes Into Rat and Human Glioblastoma Cells in Vitro and in Vivo

Abstract

Gene transfer of Lac Z and TNF-α gene was performed in several glioblastoma cell lines in vitro (A172, F98, U373-MG, HS683, U343-MG, N31, N64, N28, N39 and N65). In comparison to the calcium phosphate precipitation technique (CPPT) the cationic liposomes were more successful measured by marker gene transfer (0.76 or 2.0%, depending on the cell line). In contrast, the amount of released human TNF-α was independed from the chosen transfer technique. Since the vector pWG29del3-hTNF contains a hormone response element it was possible to stimulate the hTNF secretion by dexamethasone up to 18 fold from a basic level of 1.1 ng/ml/24h/5×10⁵ cells. A liposomal mediated marker gene transfer (Lac Z) into a rat glio-blastoma in vivo revealed a three layer area of transfected cells around the stereotactical injection channel.