Paromomycin and neomycin B derived cationic lipids: synthesis and transfection studies.

Cationic lipid-based nonviral gene delivery is an attractive approach for therapeutic gene transfer. Basically, gene transfection can be achieved by using synthetic vectors that compact DNA, forming cationic lipoplexes which can interact with the cell plasma membrane by electrostatic interactions. Among the basic components of any cationic lipid, the type of cationic headgroup has been shown to have a major role in transfection efficiency. We have previously reported the DNA transfection potential of vectors characterized by a kanamycin A headgroup. The encouraging transfection results obtained with these compounds prompted us to evaluate the potential of cationic lipids bearing headgroups based on other aminoglycosides. Thus, we herein report the synthesis and gene transfection properties of novel cationic lipids consisting of cholesteryl or dioleyl moieties linked, via various spacers, to paromomycin or neomycin B headgroups. Our results confirm that these new aminoglycoside-based cationic lipids are efficient for gene transfection both in vitro and into the mouse airways in vivo. We also investigated physico-chemical properties of the DNA complexes formed by this particular type of synthetic vectors in order to better understand their structure-activity relationships.

Self-assembled lamellar complexes of siRNA with lipidic aminoglycoside derivatives promote efficient siRNA delivery and interference.

RNA interference requires efficient delivery of small double-stranded RNA molecules into the target cells and their subsequent incorporation into RNA-induced silencing complexes. Although current cationic lipids commonly used for DNA transfection have also been used for siRNA transfection, a clear need still exists for better siRNA delivery to improve the gene silencing efficiency. We synthesized a series of cationic lipids characterized by head groups bearing various aminoglycosides for specific interaction with RNA. siRNA complexation with such lipidic aminoglycoside derivatives exhibited three lipid/siRNA ratio-dependent domains of colloidal stability. Fluorescence and dynamic light-scattering experiments showed that cationic lipid/siRNA complexes were formed at lower charge ratios, exhibited a reduced zone of colloidal instability, and had smaller mean diameters compared with our previously described guanidinium-based cationic lipids. Cryo-transmission electron microscopy and x-ray-scattering experiments showed that, although the final in toto morphology of the lipid/siRNA complexes depended on the aminoglycoside type, there was a general supramolecular arrangement consisting of ordered lamellar domains with an even spacing of 67 A. The most active cationic lipid/siRNA complexes for gene silencing were obtained with 4,5-disubstituted 2-deoxystreptamine aminoglycoside derivatives and were characterized by the siRNA being entrapped in small particles exhibiting lamellar microdomains corresponding to siRNA molecules sandwiched between the lipid bilayers. These results clearly show that lipidic aminoglycoside derivatives constitute a versatile class of siRNA nanocarriers allowing efficient gene silencing.

Kanamycin A-derived cationic lipids as vectors for gene transfection.

Cationic lipids nowadays constitute a promising alternative to recombinant viruses for gene transfer. We have recently explored the transfection potential of a new class of lipids based upon the use of aminoglycosides as cationic polar headgroups. The encouraging results obtained with a first cholesterol derivative of kanamycin A prompted us to investigate this family of vectors further, by modulating the constituent structural units of the cationic lipid. For this study, we have investigated the transfection properties of a series of new derivatives based on a kanamycin A scaffold. The results primarily confirm that aminoglycoside-based lipids are efficient vectors for gene transfection both in vitro and in vivo (mouse airways). Furthermore, a combination of transfection and physicochemical data revealed that some modifications of the constitutive subunits of kanamycin A-based vectors were associated with substantial changes in their transfection properties.

Novel cationic lipids incorporating an acid-sensitive acylhydrazone linker: synthesis and transfection properties.

Cationic lipid-mediated gene transfection involves uptake of the lipid/DNA complexes via endocytosis, a cellular pathway characterized by a significant drop in pH. Thus, in the present study, we aimed to explore the impact on transfection efficiency of the inclusion of an acid-sensitive acylhydrazone function in the cationic lipid structure. We synthesized and evaluated the transfection properties of a series of four cationic steroid derivatives characterized by an acylhydrazone linkage connecting a guanidinium-based headgroup to a saturated cholestanone or an unsaturated cholest-4-enone hydrophobic domain. Acid-catalyzed hydrolysis was confirmed for all lipids, its rate being highest for those with a cholestanone moiety. The compound bis-guanidinium bis(2-aminoethyl)amine hydrazone (BGBH)-cholest-4-enone was found to mediate efficient gene transfection into various mammalian cell lines in vitro and into the mouse airways in vivo. In vitro transfection studies with BGBH-cholest-4-enone formulations also showed that incorporation of a degradable acylhydrazone bond led to low cytotoxicity and impacted the intracellular trafficking of the lipoplexes. Thus, our work allowed us to identify a cationic lipid structure with an acid-cleavable acylhydrazone linker capable of mediating efficient gene transfection in vitro and in vivo and it thereby provides a basis for further development of related acid-sensitive gene delivery systems.

Gene transfection into fetal sheep airways in utero using guanidinium-cholesterol cationic lipids.

BACKGROUND: Over the last several years, we have developed a novel class of cationic lipids, cholesterol derivatives characterized by polar head groups with guanidinium functions. We have in particular shown that bis(guanidinium)-tren-cholesterol/dioleoylphosphatidylethanolamine (BGTC/DOPE) cationic liposomes can mediate efficient gene transfection into the mouse airways in vivo via direct intratracheal administration or intranasal instillation. As prenatal gene therapy may be necessary for the treatment of a variety of congenital lung diseases, we have explored in the present work the feasibility of BGTC-mediated gene transfection into the respiratory tract of fetal sheep in utero. METHODS: Thus, BGTC/DOPE liposomes were complexed with plasmids expressing the Escherichia coli chloramphenicol acetyltransferase (CAT) reporter gene and the resulting lipoplexes were administered to fetal sheep at 70 days of gestation via surgical replacement of the airway fluid by the transfection mixture followed by tracheal occlusion. The fetal lungs and tracheas were harvested at 72 h and examined for CAT expression and evidence of toxicity. RESULTS: CAT expression was detected in both lung and trachea homogenates, no CAT expression being observed in control fetuses receiving naked plasmid DNA. Immunohistochemical analysis showed that airway epithelial cells and some mesenchymal cells were transfected. Pulmonary histopathology of varied severity was however observed under our transfection conditions and manifested as focal epithelial and mesenchymal lesions. CONCLUSIONS: These results show that BGTC/DOPE liposomes can mediate gene transfection into the fetal sheep airway epithelium. They also invite the development of optimized BGTC-based formulations and administration conditions with a view to future prenatal gene transfer experiments involving therapeutic genes.

Combined suicide gene therapy for pancreatic peritoneal carcinomatosis using BGTC liposomes.

Peritoneal dissemination is a common end-stage complication of pancreatic cancer for which novel therapeutic modalities are actively investigated, as there is no current effective therapy. Thus, we evaluated, in a mouse model of pancreatic peritoneal carcinomatosis, the therapeutic potential of a novel nonviral gene therapy approach consisting of bis-guanidinium-tren-cholesterol (BGTC)-mediated lipofection of a combined suicide gene system. Human BxPC-3 pancreatic cells secreting the carcinoembryonic antigen (CEA) tumor marker were injected into the peritoneal cavity of nude mice. After 8 days, intraperitoneal (i.p.) lipofection was performed using BGTC/DOPE cationic liposomes complexed with plasmids encoding the two prodrug-activating enzymes Herpes Simplex Virus thymidine kinase and Escherichia coli cytosine deaminase, the latter being expressed from a bicistronic cassette also encoding E. coli uracil phosphoribosyltransferase. Administration of the lipoplexes was followed by treatment with the corresponding prodrugs ganciclovir and 5-fluorocytosine. The results presented herein demonstrate that BGTC/DOPE liposomes can efficiently mediate gene transfection into peritoneal tumor nodules. Indeed, HSV-TK mRNA was detected in tumor nodule tissues by semiquantitative reverse transcription-polymerase chain reaction analysis. In addition, green fluorescent protein (GFP) fluorescence and X-gal staining were observed in the peritoneal tumor foci following lipofection of the corresponding EGFP and LacZ reporter genes. These expression analyses also showed that transgene expression lasted for about 2 weeks and was preferential for the tumor nodules, this tumor preference being in good agreement with the absence of obvious treatment-related toxicity. Most importantly, mice receiving the full treatment scheme (BGTC liposomes, suicide genes and prodrugs) had significantly lower serum CEA levels than those of the various control groups, a finding indicating that peritoneal carcinomatosis progression was strongly reduced in these mice. In conclusion, our results demonstrate the therapeutic efficiency of BGTC-mediated i.p. lipofection of a combined suicide gene system in a mouse peritoneal carcinomatosis model and suggest that BGTC-based prodrug-activating gene therapy approaches may constitute a potential treatment modality for patients with peritoneal carcinomatosis and minimal residual disease.

Gene therapy for hepatocellular carcinoma using non-viral vectors composed of bis guanidinium-tren-cholesterol and plasmids encoding the tissue inhibitors of metalloproteinases TIMP-2 and TIMP-3.

Metalloproteinases (MMPs) and their natural inhibitors (TIMPs) contribute to the regulation of tumor microenvironment. Their expressions are deregulated in almost all human cancers. We report a novel approach to gene therapy of hepatocellular carcinoma (HCC), using repeated injections of DNA plasmids encoding the tissue inhibitors of metalloproteinases (TIMPs) TIMP-2 or TIMP-3, and a novel competent formulation of gene transfer based on nontoxic cationic cholesterol derivatives. The new gene delivery system was efficient in demonstrating the antitumor efficiency of TIMP-2 or TIMP-3 in inhibiting tumor growth of human HuH7 HCC cells xenografted into nude mice. We show, for the first time, an in vivo effect of TIMP-3 in delaying HCC tumor growth. No treatment-related toxicity was noted. An inhibition of angiogenesis and tumor necrosis accompanied the inhibitory effects of TIMP-2 or TIMP-3 on tumor expansion and invasion. We also report a bystander effect produced by transfected HuH7 tumor cells mixed with untransfected cells in 1:1 ratio in culture that resulted in killing 98% of cells within 96 h. In addition, the soluble forms of TIMP-2 and TIMP-3 expressed by transfected cells exerted a cytotoxic effect on untransfected HuH7 cell cultures. Taken together, these results demonstrate the potential efficacy of repeated treatment of secreted TIMP-2 and TIMP-3 for the design of nonviral gene therapy for hepatocarcinoma.

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.

Progress in gene delivery by cationic lipids: guanidinium-cholesterol-based systems as an example.

Artificial self-assembling systems are currently widely investigated as an alternative approach to recombinant viruses for gene transfection in vitro and in vivo. Cationic lipids are particularly attractive, as a great variety of well-characterized reagents can be synthesized from there. Over the last few years, numerous cationic lipid systems have been developed and shown to be efficient for in vitro transfection. However, although some promising results have been reported in the in vivo setting (even in clinical gene therapy trials in man), the in vivo use of cationic lipid-based systems is still problematic, especially when considering the systemic route of administration. Herein, we summarize our own research on a particular class of cationic lipids, cholesterol derivatives characterized by polar headgroups with guanidinium functions, in order to illustrate the basic principles of and the positive results already obtained by cationic lipid-mediated gene delivery as well as the remaining problems that need to be urgently resolved, particularly as regards the systemic administration. In this forward-looking review, we also discuss the present efforts to develop modular systems for improved in vivo transfection. Indeed, lipid-based vectors offer the possibility to create sophisticated modular gene delivery systems capable of self-assembly via hydrophobic interaction between their components, the role of the different functional elements being to help in overcoming the distinct extracellular and cellular barriers to in vivo gene transfection into the various somatic target tissues.