Structure Relationship of Cationic Lipids on Gene Transfection Mediated by Cationic Liposomes

The aim of this study was to investigate the transfection efficiency of cationic liposomes formulated with phosphatidylcholine (PC) and novel synthesized diethanolamine-based cationic lipids at a molar ratio of 5:1 in comparison with Lipofectamine™ 2000. Factors affecting transfection efficiency and cell viability, including the chemical structure of the cationic lipids, such as different amine head group (diamine and polyamine; and non-spermine and spermine) and acyl chain lengths (C14, C16, and C18) and the weight ratio of liposomes to DNA were evaluated on a human cervical carcinoma cell line (HeLa cells) using the pDNA encoding green fluorescent protein (pEGFP-C2). Characterizations of these lipoplexes in terms of size and charge measurement and agarose gel electrophoresis were performed. The results from this study revealed that almost no transfection was observed in the liposome formulations composed of cationic lipids with a non-spermine head group. In addition, the transfection efficiency of these cationic liposomes was in the following order: spermine-C14 > spermine-C16 > spermine-C18. The highest transfection efficiency was observed in the formulation of spermine-C14 liposomes at a weight ratio of 25; furthermore, this formulation was safe for use in vitro. In conclusion, cationic liposomes containing spermine head groups demonstrated promising potential as gene carriers.Key words: cationic lipids, cationic liposomes, gene transfection     

Development of a fluid functionalized lipidic matrix applied to direct in situ polynucleotide detection

This work presents a new approach for direct detection of polyelectrolytes at the air-water interface, based on the investigation of the interfacial properties of an active lipidic matrix especially designed for polynucleotide immobilization. A synthetic lipid with a cationic spermine headgroup, DiOctadecylamidoGlycylSpermine (DOGS), was spread at the interface to form a distortable film able to capture polynucleotides. The control of the organization state of this functionalized monolayer upon compression was achieved by recording surface pressure-area (pi-A) isotherm diagrams, presenting a specific shape with a typical liquid expanded-liquid condensed phase transition on a pure water subphase. In the presence of various dsDNA concentrations in the subphase, the isotherms were markedly modified in a time and concentration-dependent manner. The main modifications, corresponding to a large shift towards higher molecular areas and a clear fading of the phase transition, were corroborated by the fine analysis of the monolayer compressibility profile, thus suggesting a characteristic change in the monolayer fluidity as a function of both time and DNA concentration. Moreover, an ATR-Fourier transform infrared (ATR-FTIR) characterization showed evidences for the adsorption of DNA strands onto the lipidic matrix. The direct observation of the mixed monolayer morphology by Brewster angle microscopy (BAM) strongly suggests that DNA adsorption induces a reorganization of lipids at the interface, as evidenced by the change in the condensed lipidic domains morphology in the presence of DNA in the subphase. The immobilization of various polynucleotidic probes of 4000, 400 and 22 base length, confirmed by fluorescence microscopy, had similar effects on DOGS interfacial properties. Preliminary studies are finally presented to explore the possibility of using this system for the study of hybridization between complementary strands. Hence, this study demonstrates this functionalized matrix behaves as a fluid support where polynucleotide immobilization induces interfacial properties modifications, which could be further exploited through the experimental characterization of Faraday instabilities sensitive to visco-elasticity variations.     

Cationic lipids and cationic ligands induce DNA helix denaturation: detection of single stranded regions by KMnO4 probing

Cationic lipids and cationic polymers are widely used in gene delivery. Using 1,2-dioleoyl-3-trimethylammonium-propane (DOTAP) as a cationic lipid, we have investigated the stability of the DNA in DOTAP:DNA complexes by probing with potassium permanganate (KMnO4). Interestingly, thymidines followed by a purine showed higher susceptibility to cationic ligand-mediated melting. Similar studies performed with other water-soluble cationic ligands such as polylysine, protamine sulfate and polyethyleneimine also demonstrated melting of the DNA but with variations. Small cations such as spermine and spermidine and a cationic detergent, cetyl trimethylammonium bromide, also rendered the DNA susceptible to modification by KMnO4. The data presented here provide direct proof for melting of DNA upon interaction with cationic lipids. Structural changes subsequent to binding of cationic lipids/ligands to DNA may lead to instability and formation of DNA bubbles in double-stranded DNA.     

In Vivo Gene Transfer to the Mouse Nasal Cavity Mucosa Using a Stable Cationic Lipid Emulsion

We evaluate a new cationic emulsion as a mucosal gene carrier and elucidate the relationship between the transfection efficiency and the stability of the carrier/DNA complex. A cationic lipid emulsion was formulated with soybean oil and 1,2-dioleoyl-sn-glycero-3-trimethylammonium-propane (DOTAP) as major components and was used to transfer genes to the epithelial cells of the mouse nasal cavity via intranasal instillation. Correlation between the transfection efficiency and the stability of the carrier/DNA complex was investigated by measuring the carrier size changes and by observing the degree of DNA protection against DNase I digestion in the presence of heparin. The cationic emulsion showed at least 3 times better transfection activity than the liposomal carriers in nasal mucosae. The cationic emulsion was stable in the presence of heparin whereas the liposomal carriers became very unstable. Unlike DNA in liposome/DNA complexes, DNA in the emulsion/DNA complex was resistant to heparin exchange and DNase I digestion. The cationic emulsion was more effective in delivering DNA to nasal mucosae than commercially available liposomal carriers. The transfection activities of the lipid carriers in nasal cavity mucosae are in agreement with the stability of the lipid carriers and their complexes with DNA.     

Contribution of hydrophobicity to thermodynamics of ligand-DNA binding and DNA collapse

The importance of understanding the dynamics of DNA condensation is inherent in the biological significance of DNA packaging in cell nuclei, as well as for gene therapy applications. Specifically, the role of ligand hydrophobicity in DNA condensation has received little attention. Considering that only multivalent cations can induce true DNA condensation, previous studies exploring monovalent lipids have been unable to address this question. In this study we have elucidated the contribution of the hydrophobic effect to multivalent cation- and cationic lipid-DNA binding and DNA collapse by studying the thermodynamics of cobalt hexammine-, spermine-, and lipospermine-plasmid DNA binding at different temperatures. Comparable molar heat capacity changes (DeltaC(p)) associated with cobalt hexammine- and spermine-DNA binding (-23.39 cal/mol K and -17.98 cal/mol K, respectively) suggest that upon binding to DNA, there are insignificant changes in the hydration state of the methylene groups in spermine. In contrast, the acyl chain contribution to the DeltaC(p) of lipospermine-DNA binding (DeltaC(p ) = DeltaC(p lipospermine) - DeltaC(p spermine)) is significant (-220.94 cal/mol K). Although lipopermine induces DNA ordering into "tubular" suprastructures, such structures do not assume toroidal dimensions as observed for spermine-DNA complexes. We postulate that a steric barrier posed by the acyl chains in lipospermine precludes packaging of DNA into dimensions comparable to those found in nature.     

Polyamines antagonize both the antileukemic activity and the reverse transcriptase stimulatory activity of 4,4'-diacetyldiphenylurea bis(guanylhydrazone) (DDUG)

(Diacetyldiphenylurea)bis(guanylhydrazone) (DDUG) functions as a cationic trypanocide antagonized in vivo by exogenous concomitant addition of the biologically active polyamine, spermine. It also inhibits the DNA polymerases of L1210 murine leukemia cells. We have found that DDUG stimulates Rauscher murine leukemia virus DNA polymerase activity in a manner similar to polyamines. Such stimulation does not occur if DNA synthesis is carried out on spermine + activated DNA complexes. We also show that the in vivo antileukemic activity of DDUG in the L1210 ascites mouse model is antagonized by biologically active polyamines. These studies suggest a new intracellular target for the antileukemic activity of DDUG: interference with polyamine function.     

Cationic lipophosphoramidates and lipophosphoguanidines are very efficient for in vivo DNA delivery

Two new families of cationic lipids were designed and synthesized for gene delivery, namely "lipophosphoramidates" and "lipophosphoguanidines", whose efficiency was noteworthy. The most efficient have an arsonium cation as the polar head, and the unsaturated lipidic tails (e.g. oleyl) gave the better in vivo results (mice lungs).     

Ketorolac Tromethamine Liposomes: Encapsulation and Release Studies

Liposomes loaded with ketorolac tromethamine salt were prepared by using a thin layer evaporation method. The physical properties of liposomes were studied by using atomic force microscopy (AFM) and transmission electron microscopy (TEM). The relationship between lipid composition, encapsulation efficiency, vesicle size, and the release of ketorolac tromethamine-loaded liposomes was studied. The drug content was found to be dependent on the lipidic composition used in the preparations and, in particular, vesicles containing both cationic lipids (dimethyldioctadecylammonium bromide and N-[1-(2,3-dioleoyloxy)propyl]-N,N,N-trimethylammonium chloride), and phosphatidylcholine had a higher entrapped efficiency than liposomes with phosphatidylcholine alone or in the presence of cholesterol. Finally, the cationic liposomes appear to be useful as carriers for ketorolac tromethamine to control its in vitro release.     

Ketorolac tromethamine liposomes: encapsulation and release studies

Liposomes loaded with ketorolac tromethamine salt were prepared by using a thin layer evaporation method. The physical properties of liposomes were studied by using atomic force microscopy (AFM) and transmission electron microscopy (TEM). The relationship between lipid composition, encapsulation efficiency, vesicle size, and the release of ketorolac tromethamine-loaded liposomes was studied. The drug content was found to be dependent on the lipidic composition used in the preparations and, in particular, vesicles containing both cationic lipids (dimethyldioctadecylammonium bromide and N-[1-(2,3-dioleoyloxy)propyl]-N,N,N-trimethylammonium chloride), and phosphatidylcholine had a higher entrapped efficiency than liposomes with phosphatidylcholine alone or in the presence of cholesterol. Finally, the cationic liposomes appear to be useful as carriers for ketorolac tromethamine to control its in vitro release.     

Polycationic amphiphiles based on triethylenetetramine and their transfection efficacy

Novel polycationic amphiphiles derived from triethylenetetramine, a spermine analogue, containing cholesterol or dialkylglycerol residues as hydrophilic domains were synthesized. The amphiphiles and a helper lipid 1,2-dioleoyl-sn-glycero-3-phosphoethanolamine) served for the preparation of cationic liposomes, physicochemical properties of which were evaluated. A comparative study of cytotoxicity and transfection efficiency demonstrated that the replacement of spermine by triethylenetetramine decreased transfection activity of cationic liposomes.     

Efficient Gene Delivery Using Anionic Liposome-Complexed Polyplexes (LPDII)

Synthetic gene transfer vectors based on polyplexes complexed to anionic liposomes (LPDII vectors) were characterized for their transfection efficiency in cultured mammalian cells. The effects of polycation to DNA ratio, lipid to DNA ratio, choice of polycation and lipid composition were systematically evaluated in human oral carcinoma KB cells, using a luciferase reporter gene. For LPDII formulations containing poly-L-lysine and dioeoylphosphatidylethanolamine/cholesteryl hemisuccinate (DOPE/CHEMS) anionic liposomes, at a constant lipid to DNA ratio, an increase in the polycation/DNA (N/P) ratio resulted in an increase in transfection activity. Meanwhile, the optimal lipid to DNA ratio for efficient gene delivery was influenced by the N/P ratio used, and was increased at higher N/P ratios. For the DNA condensing agent, poly-L-lysine could be replaced by polyethylenimine (PEI) as the DNA condensing agent in the formulations. For the lipidic components, CHEMS could be replaced by other anioniclipids including oleic acid, dicetylphosphate and phosphatidylserine, but DOPE, a fusogenic helper lipid, could not be replaced by dioleolyphosphatidylcholine. LPDII formulation showed significantly less cytotoxicity compared to the commonly used cationic lipsomes or PEI mediated transfection and several cell lines were transfected with high efficiency. LPDII vectors avoid the use of toxic cationic lipids and may have potential application in gene therapy.     

Acceleration of DNA strand exchange by polycation comb-type copolymer.

The accelerating effect of cationic substances on DNA strand exchange reaction between 20 bp DNA duplex and its complementary single strand was studied. A comb-type polycationic copolymer which is composed of poly (L-lysine) backbone and dextran graft chain (PLL-g-Dex) and known to stabilize triplex DNA expedites the strand exchange reaction under physiological relevant conditions. Electrostatically small excess of the copolymer increased DNA strand exchange rate by 300-fold while large excess of spermine or cethyltrimethylammonium bromide, cationic detergent known to promote markedly hybridization of complementary DNA strands, showed slight effect. It should be noted that the copolymer promotes the strand exchange reaction while it stabilizes double stranded DNA.     

Dynamics of DNA condensation

The condensation of DNA induced by spermine and spermidine is investigated by equilibrium titrations and stopped-flow and field-jump experiments using scattered light detection. The spermine concentration required for the cooperative condensation process is measured at different DNA concentrations; these data are used to evaluate both the condensation threshold degree of spermine binding and the binding constant of spermine according to an excluded-site model. Stopped-flow measurements of the spermine-induced condensation demonstrate the existence of two processes: (1) A "fast" reaction is observed in the millisecond time range, when the reactant concentrations are around 1 microM; it is associated with a characteristic induction period and is assigned to the intramolecular condensation reaction. (2) A slow reaction with time constants of, e.g., 100 s strongly dependent upon both spermine and DNA concentrations is assigned to an intermolecular DNA association. The unusual time course of the intramolecular condensation reaction with the induction period provides evidence for a "threshold kinetics". During the induction period, spermine molecules are bound to DNA, but the degree of binding remains below the threshold value. As soon as the degree of ligand binding arrives at the threshold, the DNA is condensed in a relatively fast reaction. Model calculations of the spermine binding kinetics according to an excluded-site model demonstrate that the spermine molecules bound to DNA are mobile along the double helix. A comparison of the experimental data with the results of Monte Carlo simulations suggests a rate constant of approximately 200 s-1 for spermine movement by one nucleotide residue.(ABSTRACT TRUNCATED AT 250 WORDS)     

Polyamines stimulate DNA-directed DNA synthesis catalyzed by mammalian type C retroviral DNA polymerases

In the presence of optimal concentrations of Mg2+, rates of activated (gapped) DNA-directed DNA synthesis by purified mammalian type C retroviral DNA polymerases are stimulated greater than 10-fold by the polyamines spermine and spermidine. Such stimulation was not observed using either similar concentrations of the polyamines cadaverine or putrescine or exogenously provided salt or ammonium ions. Avian type C as well as mammalian type B and type D retroviral DNA polymerases, in contrast to the mammalian type C enzyme, were found to be relatively insensitive to spermine and spermidine stimulation. Kinetic analysis of the polyamine stimulation of activated DNA-directed DNA synthesis carried out using spermine and purified Rauscher leukemia virus DNA polymerase revealed at least two distinct mechanisms of activation of DNA synthesis. 1) At DNA concentrations below 2.5 micrograms/ml, spermine appears to interact with the enzyme-DNA complex in order to stimulate synthesis. 2) At DNA concentrations above 2.5 micrograms/ml, increased spermine stimulation is observed which appears to be due to its direct interaction with the activated DNA template resulting in either selective limitation of the formation of "dead-end" enzyme-DNA complexes or its ability to convert such nonproductive enzyme binding sites into productive sites for the initiation of synthetic activity. The addition of spermine to reaction mixtures was found to increase both the apparent Km and Vmax of the activated (gapped) DNA-directed reaction with regard to template concentration.     

Recent patents in cationic lipid carriers for delivery of nucleic acids

Gene therapy is a medical technique intended for treatment of disorders caused by defective, missing, or overexpressing genes. Efficient delivery vectors are necessary in order to transport genetic material to the target cells. Such vectors include viral and non-viral carriers. Viral vectors transfect cells efficiently, however risks associated with their use have limited their clinical applications. Nonviral delivery systems are safer, easier to prepare, more versatile and cost effective. However, their transfection efficiency still falls behind that of the viral vectors. Considerable research into nonviral gene delivery has been conducted in the last two decades on synthetic soft materials such as cationic lipids, polymers, surfactants, and dendrimers as prospective nucleotide carriers for gene delivery. So far, cationic lipids are the most widely used constituents of nonviral gene carriers, with multiple strategies employed to improve their in vitro and in vivo transfection. Efforts in synthesizing new cationic lipids were not fully successful in closing the gap between the efficiency of the viral vectors and that of binary cationic lipid/DNA complexes. Current efforts for improving lipofection efficiency are focused on the development of multicomponent carriers including cationic lipids as key constituents. This review summarizes the recent patents on new cationic lipids as well as on multicomponent formulations enhancing their efficiency as nucleotide carriers.     

Systematic solid-phase synthesis of linear pseudooligolysines containing multiple adjacent CH(2)NH amide bond surrogates: potential agents for gene delivery.

Solid-phase methodology was used to synthesize a series of fully reduced linear oligolysines (pseudooligolysines, abbreviated herein as PLs) containing up to five adjacent CH2NH peptide bond isosteres. The reduced peptide bonds were introduced by the reductive alkylation reaction between Fmoc-Lys-(Boc)-al and a free alpha-amine moiety on the pseudopeptidyl resin, using sodium cyanoborohydride in an acidified mixture of NMP/CH3OH (1 : 1 v/v). The oligomeric molecules, which can be regarded as polyethylene imine and spermine analogs, possess multiple positive charges under physiological conditions and form tight complexes with plasmid DNA. These characteristics and the increased resistance to hydrolysis by trypsin make these molecules potential candidates for future use as DNA carriers in gene delivery.     

DNA photocleavage by porphyrin–polyamine conjugates

A series of polyamine–porphyrin conjugates bearing two (cis or trans position) or four units of spermidine or spermine was synthesized. We studied the binding of these cationic porphyrins to calf thymus DNA by the means of UV–vis spectroscopy and we investigated their ability to cleave plasmid DNA in the presence of light. DNA binding and DNA photocleavage abilities were found to depend on structural characteristics as (a) the relative positions of the side chains on the porphyrin ring and (b) the nature of the attached side chains (spermidine or spermine). DNA cleavage was also studied in the presence of a singlet oxygen quencher (NaN₃) and in the presence of a hydroxyl radical scavenger (mannitol). Singlet oxygen was the major species responsible for the cleavage of DNA previously observed. Collectively, these data show that polyamine–porphyrin conjugates could be promising phototherapeutic agents.     

Physicochemical properties of polymers: An important system to overcome the cell barriers in gene transfection

Delivery of the macromolecules including DNA, miRNA, and antisense oligonucleotides is typically mediated by carriers due to the large size and negative charge. Different physical (e.g., gene gun or electroporation), and chemical (e.g., cationic polymer or lipid) vectors have been already used to improve the efficiency of gene transfer. Polymer‐based DNA delivery systems have attracted special interest, in particular via intravenous injection with many intra‐ and extracellular barriers. The recent progress has shown that stimuli‐responsive polymers entitled as multifunctional nucleic acid vehicles can act to target specific cells. These nonviral carriers are classified by the type of stimulus including reduction potential, pH, and temperature. Generally, the physicochemical characterization of DNA‐polymer complexes is critical to enhance the transfection potency via protection of DNA from nuclease digestion, endosomal escape, and nuclear localization. The successful clinical applications will depend on an exact insight of barriers in gene delivery and development of carriers overcoming these barriers. Consequently, improvement of novel cationic polymers with low toxicity and effective for biomedical use has attracted a great attention in gene therapy. This article summarizes the main physicochemical and biological properties of polyplexes describing their gene transfection behavior, in vitro and in vivo. In this line, the relative efficiencies of various cationic polymers are compared. © 2015 Wiley Periodicals, Inc. Biopolymers 103: 363–375, 2015.     

New perfluorinated polycationic dimerizable detergents for the formulation of monomolecular DNA nanoparticles and their in vitro transfection efficiency

We describe the synthesis of new perfluorinated dimerizable detergents which contain a tricationic or tetracationic (linear or branched spermine, respectively) polar head, and report on their cmc, their ability to condense DNA into cationic monomolecular DNA nanoparticles as well as on the in vitro transfection efficiency of these nanoparticles. Such cationic nanoparticles were prone to display efficient cell transfection properties as a result of increased contact to the anionic cell surface and internalization by endocytosis, low size compatible with improved intracellular diffusion and nuclear pore crossing, and the presence of amine function of low pK(a) for their endosomal escape. The challenge was to design polymerizable polycationic detergents that display a cmc high enough for the monomer to perform monomolecular DNA condensation (as cationic particles) and low enough for the dimer to form stable nanoparticles capable of efficient cell transfection. Although we succeeded in formulating small-sized cationic monomolecular DNA nanoparticles (<40 nm) with these dimerizable perfluorinated spermine-based detergents for N/P ratios of up to 5 (N=number of detergent amine equivalents/P=number of DNA phosphate equivalents), these small-sized cationic nanoparticles proved to be poor non-specific transfection agents in vitro, even in the presence of chloroquine. Their poor transfection potential could be due more likely to Brownian motion which prevents these very small-sized particles from sedimentation and adsorption onto the adherent cell monolayer, and, consequently, from proteoglycan-triggered endocytosis.     

Characterization of degradable polyelectrolyte multilayers fabricated using DNA and a fluorescently-labeled poly(β-amino ester): shedding light on the role of the cationic polymer in promoting surface-mediated gene delivery

Polyelectrolyte multilayers (PEMs) fabricated from cationic polymers and DNA have been investigated broadly as materials for surface-mediated DNA delivery. One attractive aspect of this "multilayered" approach is the potential to exploit the presence of cationic polymer "layers" in these films to deliver DNA to cells more effectively. Past studies demonstrate that these films can promote transgene expression in vitro and in vivo, but significant questions remain regarding roles that the cationic polymers could play in promoting the internalization and processing of DNA. Here, we report physicochemical and in vitro cell-based characterization of DNA-containing PEMs fabricated using fluorescently end-labeled derivatives of a degradable polycation (polymer 1) used in past studies of surface-mediated transfection. This approach permitted simultaneous characterization of polymer and DNA in solution and in cells using fluorescence-based techniques, and provided information about the locations and behaviors of polymer 1 that could not be obtained using other methods. LSCM and flow cytometry experiments revealed that polymer 1 and DNA released from film-coated objects were both internalized extensively by cells and that they were colocalized to a significant extent inside cells (e.g., ~58% of DNA was colocalized with polymer). Fluorescence anisotropy measurements of solutions containing partially eroded films were also consistent with the presence of aggregates of polymer 1 and DNA in solution (e.g., after release from surfaces, but prior to internalization by cells). Our results support the view that polymer 1, which is incorporated into these materials as "layers" rather than as part of optimized, preformed "polyplexes", can act to promote or enhance surface-mediated DNA delivery. More broadly, our results suggest opportunities to improve the delivery properties of DNA-containing PEMs by incorporation of additional "layers" of other conventional cationic polymers designed to address specific intracellular barriers to transfection, such as endosomal escape, more effectively.