Design of aminated poly(1-vinylimidazole) for a new pH-sensitive polycation to enhance cell-specific gene delivery

Poly(1-vinylimidazole) (PVIm) with aminoethyl groups has been synthesized as a new pH-sensitive polycation to enhance cell-specific gene delivery. The resulting aminated PVIm (PVIm-NH2) was water-soluble despite deprotonation of the imidazole groups at physiological pH, as determined by acid-base titration and solution turbidity measurement. Hemolysis assay showed that PVIm-NH2 enhanced membrane disruptive ability at endosomal pH, owing to the protonation of the imidazole groups with a pKa value around 6.0. Agarose gel retardation assay proved that the introduced aminoethyl groups worked as anchor groups to retain DNA. Furthermore, the ternary complex of DNA, PVIm-NH2, and a poly(L-lysine) conjugated with lactose molecules, PLL-Lac, at pH 7.4 dissociated the PLL-Lac polycation by protonation of the imidazole groups of PVIm-NH2 at pH 6.0. The resulting PVIm-NH2/DNA binary complexes easily released DNA, as compared with the PLL-Lac/PVIm-NH2/DNA ternary complex, which was examined by competitive exchange with dextran sulfate. By using PVIm-NH2 as a pH-sensitive DNA carrier, as well as PLL-Lac as a cell-targeting DNA carrier, the resulting ternary complex specifically mediated the gene expression, which depended on the protonation of the imidazole groups, on human hepatoma HepG2 cells with asialoglycoprotein receptors. These results suggest that the cell-specific gene delivery mediated by PLL-Lac was enhanced by PVIm-NH2 as a new pH-sensitive polycation.     

Zinc-chelated imidazole groups for DNA polyion complex formation

This communication presents the pH-dependent chelation of Zn(2+) ions with the imidazole groups of poly(1-vinylimidazole) (PVIm) and DNA polyion complex formation with the zinc-chelated PVIm (PVIm-Zn) via chelated Zn(2+) ions. The resulting PVIm-Zn/DNA complexes exhibit no significant cytotoxicity and show outstanding gene expression.     

Ternary complex consisting of DNA, polycation, and a natural polysaccharide of schizophyllan to induce cellular uptake by antigen presenting cells

A natural polysaccharide called schizophyllan (SPG) can form a complex with polynucleotides, and the complex has been shown to deliver biofunctional short DNAs such as antisense DNAs and CpG-DNAs. Although it is a novel and efficient method, there is a drawback: attachment of homo-polynucleotide tails [for example, poly(dA) or poly(C)] to the end of DNA is necessary to stabilize the complex, because DNA heterosequences cannot bind to SPG. The aim of this paper is to present an alternative method in which SPG/DNA complexes can be made without using the tails. The basic strategy is as follows: since SPG can form hydrophobic domains in aqueous solutions, hydrophobic objects should be encapsulated by this domain. DNA alone is highly hydrophilic; however, once DNA/polycation complexes are made, they should be included by the SPG hydrophobic domain. The aim of this paper is to prove the formation of the polycation/DNA/SPG ternary complex. Gel electrophoresis showed that presence of SPG influenced the migration pattern of polycation+DNA mixtures. With increasing the SPG ratio, the zeta potential (zeta) of the polycation+DNA+SPG mixture decreased drastically to reach almost zeta = 0 and the particle size distributions were altered due to the ternary complex formation. Confocal laser scanning microscopy revealed that the polycation/DNA/SPG ternary complexes showed high uptake efficiency when the complexes were exposed to macrophage-like cells (J774.A1). IL-12 secretion was enhanced when CpG-DNA was added as the ternary complex. These features can be ascribed to the fact that J774.A1 has a SPG recognition site called Dectin-1 on the cellular surface and the ternary complex can be ingested by this pathway.     

DNA-binding transferrin conjugates as functional gene-delivery agents: synthesis by linkage of polylysine or ethidium homodimer to the transferrin carbohydrate moiety.

We have previously demonstrated that transferrin-polycation conjugates are efficient carrier molecules for the introduction of genes into eukaryotic cells. We describe here a more specific method for conjugation of transferrin with DNA-binding compounds involving attachment at the transferrin carbohydrate moiety. We used the polycation poly(L-lysine) or the DNA intercalator, ethidium homodimer as DNA-binding domains. Successful transferrin-receptor-mediated delivery and expression of the Photinus pyralis luciferase gene in K562 cells has been shown with these new transferrin conjugates. The activity of the transferrin-ethidium homodimer (TfEtD) conjugates is low relative to transferrin-polylysine conjugates; probably because of incomplete condensation of the DNA. However, DNA delivery with TfEtD is drastically improved when ternary complexes of the DNA with TfEtD and the DNA condensing agent polylysine are prepared. The gene delivery with the carbohydrate-linked transferrin-polylysine conjugates is equal or superior to described conjugates containing disulfide linkage. The new ligation method facilitates the synthesis of large quantities (greater than 100 mg) of conjugates.     

Unfolding of the RAP-D3 helical bundle facilitates dissociation of RAP-receptor complexes

The receptor-associated protein (RAP) functions as an escort protein for receptors of the low-density lipoprotein receptor (LDLR) family by preventing premature intracellular binding of ligands and assisting with delivery of mature receptors to the cell surface. The modulation of affinity by pH is believed to play an important role in the escort function of RAP, because RAP binds tightly to proteins of the LDLR family at near-neutral pH early in the secretory pathway where its high affinity precludes premature binding of ligands but then dissociates from bound receptors at the lower pH of the Golgi compartment. The third domain of RAP (RAP-D3), which forms a three-helix bundle, is sufficient to reconstitute the escort activity. Here, we test the hypothesis that low-pH induced unfolding of the RAP-D3 helical bundle facilitates dissociation of RAP-receptor complexes. First, variants of RAP-D3 resistant to low pH-induced unfolding were constructed by replacing interior histidine residues with phenylalanines. In contrast to native RAP-D3, which exhibits an unfolding pKa of 6.3 and a Tm of 42 degrees C, the most hyperstable variant of RAP-D3, in which four histidine residues are replaced with phenylalanine, has an unfolding pKa of 4.8, and a Tm of 58 degrees C. The phenylalanine substitutions in RAP-D3 confer increased stability to pH-induced dissociation of complexes formed between RAP-D3 and a two-repeat fragment of the LDLR (LA3-4). When introduced into full-length RAP, the four mutations that confer hyperstability on RAP-D3 interfere with transport of endogenous LRP-1 to the cell surface in a dominant negative fashion under conditions where expression of normal RAP has no effect on LRP-1 transport. Our studies support a model in which low pH-dependent unfolding of RAP-D3 facilitates dissociation of RAP from the LA repeats of LDLR family proteins in the mildly acidic pH of the Golgi.     

Successful Transfection of Lymphocytes by Ternary Lipoplexes

Transgene expression in lymphoid cells may be useful for modulating immune responses in, and gene therapy of, cancer and AIDS. Although cationic liposome-DNA complexes (lipoplexes) present advantages over viral vectors, they have low transfection efficiency, unfavorable features for intravenous administration, and lack of target cell specificity. The use of a targeting ligand (transferrin), or an endosome-disrupting peptide, in ternary complexes with liposomes and a luciferase plasmid, significantly promoted transgene expression in several T- and B-lymphocytic cell lines. The highest levels of luciferase activity were obtained at a lipid/DNA (±) charge ratio of 1/1, where the ternary complexes were net negatively charged. The use of such negatively charged ternary complexes may alleviate some of the drawbacks of highly positively charged plain lipoplexes for gene delivery.     

Novel biodegradable poly(disulfide amine)s for gene delivery with high efficiency and low cytotoxicity

Novel biodegradable poly(disulfide amine)s with defined structure, high transfection efficiency, and low cytotoxicity were designed and synthesized as nonviral gene delivery carriers. Michael addition between N, N'-cystaminebisacrylamide (CBA) and three N-Boc protected diamines ( N-Boc-1,2-diaminoethane, N-Boc-1,4-diaminobutane, and N-Boc-1,6-diaminohexane) followed by N-Boc deprotection under acidic condition resulted in final cationic polymers with disulfide bonds, tertiary amine groups in main chains, and pendant primary amine groups in side chains. Polymer structures were confirmed by 1H NMR, and their molecular weights were in the range 3.3-4.7 kDa with narrow polydispersity (1.12-1.17) as determined by size exclusion chromatography (SEC). Acid-base titration assay showed that the poly(disulfide amine)s possessed superior buffering capacity to branched PEI 25 kDa in the pH range 7.4-5.1, which may facilitate the escape of DNA from the endosomal compartment. Gel retardation assay demonstrated that significant polyplex dissociation was observed in the presence of 5.0 mM DTT within 1 h, suggesting rapid DNA release in the reduction condition such as cytoplasm due to the cleavage of disulfide bonds. Genetic transfections mediated by these poly(disulfide amine)s were side-chain spacer length dependent. The poly(disulfide amine) with a hexaethylene spacer, poly(CBA-DAH), had comparable transfection efficiency to bPEI 25 kDa in the tested cell lines, i.e., 293T cells, Hela cells, and NIH3T3 cells. This same poly(disulfide amine) mediated 7-fold higher luciferase expression than bPEI 25 kDa in C2C12 cells (mouse myoblast cell line), a cell line difficult to transfect with many cationic polymers. Furthermore, MTT assay indicated that all three poly(disulfide amine)s/pDNA polyplexes were significantly less toxic than bPEI/pDNA complexes.     

Single-cycle kinetic analysis of ternary DNA complexes by surface plasmon resonance on a decaying surface

Complexes involving three DNA strands were used to demonstrate that the single-cycle kinetics (SCK) method, which consists in injecting sequentially samples at increasing concentrations and until now used exclusively to investigate bimolecular complexes by surface plasmon resonance, can be extended to the kinetic analysis of ternary complexes. DNA targets, B, were designed with sequences of variable lengths on their 3' sides that recognise a surface-immobilized biotinylated DNA anchor, A. These targets displayed on their 5' sides sequences that recognise DNA oligonucleotides of variable lengths, C, namely the analytes. Combinations of B and C DNA oligonucleotides on A generated ternary complexes each composed of two Watson-Crick helices displaying different kinetic properties. The target-analyte B-C duplexes were formed by sequentially injecting three increasing concentrations of the analytes C during the dissociation phase of the target B from the anchor A. The sensorgrams for the target-analyte complexes dissociating from the functionalized surface were successfully fitted by the SCK method while the target dissociated from the anchor, i.e. on a decaying surface. Within the range of applicability of the method which is driven by the rate of dissociation of the target from the anchor, the rate and equilibrium constants characteristic of these target-analyte duplexes of the ternary complexes did not depend on how fast the targets dissociated from the immobilized DNA anchor. In addition the results agreed very well with those obtained when such duplexes were analysed directly as bimolecular complexes, i.e. when the target, modified with a biotin, was directly immobilized onto a streptavidin sensor chip surface rather than captured by an anchor. Therefore the method we named SCKODS (Single-Cycle Kinetics On a Decaying Surface) can also be used to investigate complexes formed during a dissociation phase, in a ternary complex context. The SCKODS method can be combined with the SCK one to fully characterize the two bimolecular complexes of a ternary complex.     

Transfer of recA protein from one polynucleotide to another. Kinetic evidence for a ternary intermediate during the transfer reaction

We have analyzed the transfer kinetics of recA protein from one polynucleotide to another by monitoring the change in fluorescence of a modified single-stranded M13 DNA, referred to as etheno M13 DNA, that accompanies recA protein dissociation. The observed rate of transfer is dependent on the concentration of competitor polynucleotide, polythymidylic acid (poly(dT]; increasing the poly(dT) concentration increases the rate of transfer. These data are inconsistent with the rate-limiting step in the transfer mechanism occurring by a simple dissociation process. Under certain conditions, the apparent rate constant displays plateau behavior at high poly(dT) concentrations. This result is indicative of transfer occurring through a ternary intermediate including etheno M13 DNA and poly(dT). The transfer reaction was found to occur through two kinetically distinct species of transferring recA protein X DNA complexes. The relative amounts of these two species was affected by both the MgCl2 and protein concentration, suggesting that the two kinetic components reflect different aggregation states of the recA protein X DNA complex. Because etheno M13 DNA and poly(dT) contain no complementary sequences, we have concluded that recA protein has the intrinsic ability to form a kinetic ternary intermediate with two separate single-stranded DNA molecules in the absence of homology.     

Dependence of the cellular internalization and transfection efficiency on the structure and physicochemical properties of cationic detergent/DNA/liposomes

BACKGROUND: Control of the structure and physicochemical properties of DNA complexed with nonviral vectors is essential for efficient biodistribution and gene delivery to cells. Cationic liposomes interact with DNA giving transfection competent but large and heterogeneous aggregates. On the other hand, cationic detergents condense DNA into small homogeneous but reversible complexes inefficient for transfection. METHODS: In order to combine the favorable features of both vectors, ternary complexes were prepared by adding cationic liposomes to plasmid DNA condensed by cationic detergents. The structure and physicochemical properties of these complexes were investigated by electron microscopy, quasi-elastic light scattering, gel electrophoresis and fluorescence techniques. These data were then correlated with the transfection efficiency and intracellular trafficking of the ternary complexes determined by luciferase gene expression and confocal microscopy, respectively. RESULTS: The ternary complexes were found to form small, homogeneous, globular, stable and positively charged particles with a highly dense and packed lamellar internal structure differing from the multilamellar structure (L(alpha)(C)) of the corresponding lipoplexes. In the presence of serum, the ternary complexes were more efficiently internalized into cells, less toxic and showed 20-fold higher transfection efficiency than lipoplexes. CONCLUSIONS: This study showed that small, monodisperse and highly stable complexes could be obtained by precompaction of DNA with cetyltrimethylammonium bromide, followed by addition of cationic lipids. The higher efficiency of the ternary complexes with respect to their corresponding lipoplexes was related to their internal structure which prevents their dissociation by serum proteins and allows efficient internalization in the target cells.     

Effect of albumin and polyanion on the structure of DNA complexes with polycation containing hydrophilic nonionic block.

Self-assembling systems based on ionic complexes of DNA with block copolymer of N-(2-hydroxypropyl)methacrylamide with 2-(trimethylammonio)ethyl methacrylate were studied as systems suitable for gene delivery. In this study, the influence of albumin and polyanion on parameters of the DNA polyelectrolyte complexes in aqueous solutions was investigated. Static and dynamic light-scattering methods were used as a main tool for characterizing these interactions. It was found that albumin is not able to release free DNA, but it can rather bind to the complexes forming ternary DNA-polycation-albumin complexes with increased hydrodynamic radii of about 10 nm. Polyanion tested, sodium poly(styrenesulfonate), was able to release free DNA in the presence of a low-molecular-weight electrolyte. In the absence of a low-molecular-weight electrolyte, only formation of ternary complexes and no DNA release was observed. The in vivo biodistribution analysis of DNA complexes showed no effect of the presence of hydrophilic nonionic poly(HPMA) on the circulatory time or organ distribution. The interaction of DNA complexes with albumin and other plasma proteins was suggested to be a major reason for the short circulatory times.     

Receptor-Mediated Transfer of DNA–Galactosylated Poly-L-lysine Complexes into Mammalian Cells in vitro and in vivo

With the goal of developing non-viral techniques for exogenous gene delivery into mammalian cells, we have studied receptor-mediated gene transfer using complexes of plasmid DNA and galactosylated poly-L-lysine, poly(L-Lys)Gal. To evaluate the optimal parameters for efficient gene transfer into human hepatoma HepG2 cells by the DNA–poly(L-Lys)Gal complexes, the bacterial reporter genes lacZ and cat were used. Examination of the reporter gene expression level showed that the efficiency of DNA delivery into the cells depends on the structure of DNA–poly(L-Lys)Gal complexes formed at various ionic strength values. The efficiency of DNA transfer into the cells also depends on DNA/poly(L-Lys)Gal molar ratio in the complexes. Plasmid vector carrying human apolipoprotein A-I (apoA-I) gene was injected as its complex with poly(L-Lys)Gal into rat tail vein. Some level of ApoA-I was detected in the serum of the injected rats. Also, the human apoA-I-containing plasmid was found to be captured specifically by the rat liver cells and transported into the cell nuclei, where it can persist as an episome-like structure for at least a week. After repeated injections of DNA–poly(L-Lys)Gal complexes, the level of human ApoA-I in rat serum increases, probably, due to accumulation of functional human apoA-I gene in the liver cell nuclei. The data seem to be useful for the development of non-viral approaches to gene therapy of cardiovascular diseases.     

Targeted transfection of human hepatoma cells with a combination of lipospermine and neo-galactolipids

Abstract

Optimal in vitro gene delivery with (poly)cationic amphiphiles requires an excess of cationic charges with respect to DNA phosphates. We have developed targeted transfection systems based on electrically neutral lipospermine/DNA particles, to which synthetic tri-antennary galactose ligands were conjugated to provide an interaction with cells, such as HepG2 cells, that express Gal/GalNAc receptors at their surface. Transfection, which was cell specific, increases ? 1000-fold with 25% neogalactolipid, i.e. approaching the value observed with optimized positively charged transfection complexes. Unexpectedly, neutral particles containing thiol-reactive phospholipids, were also efficient gene delivery systems, although non cell specific.     

Transferrin-Associated Lipoplexes as Gene Delivery Systems: Relevance of Mode of Preparation and Biophysical Properties

The successful application of gene therapy depends highly on understanding the properties of gene carriers and their correlation with the ability to mediate transfection. An important parameter that has been described to improve transfection mediated by cationic liposomes involves association of ligands to cationic liposome–DNA complexes (lipoplexes). In this study, ternary complexes composed of 1,2-dioleoyl-3-(trimethylammonium) propane:cholesterol, plasmid DNA and transferrin (Tf, selected as a paradigm of a ligand) were prepared under various conditions, namely, in medium with different ionic strengths (HEPES-buffered saline [HBS] or dextrose), at different lipid/DNA (+/–) charge ratios and using different modes for component addition. We investigated the effect of these formulation parameters on transfection (in the absence and presence of serum), size of the complexes, degree of DNA protection and extent of their association with cells (in terms of both lipid and DNA). Our results show that all the tested parameters influenced to some extent the size of the complexes and their capacity to protect the carried genetic material, as well as the levels of cell association and transfection. The best transfection profile was observed for ternary complexes (Tf-complexes) prepared in high ionic strength solution (HBS), at charge ratios close to neutrality and according to the following order of component addition: cationic liposomes–Tf–DNA. Interestingly, in contrast to what was found for dextrose–Tf-complexes, transfection mediated by HBS-Tf-complexes in the presence of serum was highly enhanced.     

Enhanced nuclear import and transfection efficiency of TAT peptide-based gene delivery systems modified by additional nuclear localization signals

Cellular uptake and nuclear localization are two major barriers in gene delivery. In order to evaluate whether additional nuclear localization signals (NLSs) can improve gene transfection efficiency, we introduced different kinds of NLSs to TAT-based gene delivery systems to form three kinds of complexes, including TAT-PV/DNA, TAT/DNA/PV, and TAT/DNA/HMGB1. The DNA binding ability of different vectors was evaluated by agarose gel electrophoresis. The in vitro transfections mediated by different complexes under different conditions were carried out. The cells treated by different complexes were observed by confocal microscopy. The MTT assay showed that all complexes did not exhibit apparent cytotoxicity in both HeLa and Cos7 cell lines even at high N/P ratios. The luciferase reporter gene expression mediated by TAT-PV/DNA complexes exhibited about 200-fold enhancement as compared with TAT/DNA complexes. Confocal study showed that, except TAT/DNA/PV, all other complexes exhibited enhanced nuclear accumulation and cellular uptake in both HeLa and Cos7 cell lines. These results indicated that the introduction of nuclear localization signals could enhance the transfection efficacy of TAT-based peptides, implying that the TAT peptide-based vectors demonstrated here have promising potential in gene delivery.     

Structural advantage of dendritic poly(L-lysine) for gene delivery into cells

This study aimed to investigate the relationships between structures of gene carrier molecules and their activities for gene delivery into cells. We compared 2 types of poly(L-lysine) as carriers, that is, dendritic poly(L-lysine) (KG6) and linear poly(L-lysine) (PLL). KG6 formed a neutral DNA complex, and its DNA compaction level was weaker than that of PLL. The amount of DNA binding and uptake into cells mediated by PLL was 4-fold higher than that with KG6. However, KG6-mediated gene expression was 100-fold higher than that by PLL. Since pK(a) values of terminal amines of KG6 were lowered even though small amounts of DNA were internalized into cells, sufficient DNA amounts for effective gene expression escaped to the cytosol due to the proton sponge effect in the endosome. In addition, weakly compacted DNA with KG6 was advantageous in accessing RNA polymerase in the cell nucleus. On the other hand, PLL did not show the proton sponge effect in the endosome and resulted in strong compaction of DNA. Even though large DNA amounts were internalized into cells, most of the DNA would not take part in gene expression systems in the nucleus. Amount of induced cytokine production after intravenous injection of DNA complexes with KG6 and PLL was low, and was similar to the case when DNA was injected alone. Therefore, no significant difference in effects on cytokine production was observed between KG6 and PLL.     

Novel shielded transferrin-polyethylene glycol-polyethylenimine/DNA complexes for systemic tumor-targeted gene transfer

Tumor-targeting DNA complexes which can readily be generated by the mixing of stable components and freeze-thawed would be very advantageous for their subsequent application as medical products. Complexes were generated by the mixing of plasmid DNA, linear polyethylenimine (PEI22, 22 kDa) as the main DNA condensing agent, PEG-PEI (poly(ethylene glycol)-conjugated PEI) for surface shielding, and Tf-PEG-PEI (transferrin-PEG-PEI) to provide a ligand for receptor-mediated cell uptake. Within the shielding conjugates, PEG chains of varying size (5, 20, or 40 kDa) were conjugated with either linear PEI22 (22 kDa) or branched PEI25 (25 kDa). The three polymer components were mixed together at various ratios with DNA; particle size, surface charge, in vitro transfection activity, and systemic gene delivery to tumors was investigated. In general, increasing the proportion of shielding conjugate in the complex reduced surface charge, particle size, and in vitro transfection efficiency in transferrin receptor-rich K562 cells. The particle size or surface charge of the complexes containing the PEG-PEI conjugate did not significantly change after freeze-thawing, while complexes without the shielding conjugate aggregated. Complexes containing PEG-PEI conjugate efficiently transfected K562 cells after freeze-thawing. Furthermore the systemic application of freeze-thawed complexes exhibited in vivo tumor targeted expression. For complexes containing the luciferase reporter gene the highest expression was found in tumor tissue of mice. An optimum formulation for in vivo application, PEI22/Tf-PEG-PEI/PEI22-PEG5, containing plasmid DNA encoding for the tumor necrosis factor (TNF-alpha), inhibited tumor growth in three different murine tumor models. These new DNA complexes offer simplicity and convenience, with tumor targeting activity in vivo after freeze-thawing.     

Human serum albumin enhances DNA transfection by lipoplexes and confers resistance to inhibition by serum

Cationic liposome-DNA complexes ('lipoplexes') are used as gene delivery vehicles and may overcome some of the limitations of viral vectors for gene therapy applications. The interaction of highly positively charged lipoplexes with biological macromolecules in blood and tissues is one of the drawbacks of this system. We examined whether coating cationic liposomes with human serum albumin (HSA) could generate complexes that maintained transfection activity. The association of HSA with liposomes composed of 1, 2-dioleoyl-3-(trimethylammonium) propane and dioleoylphosphatidylethanolamine, and subsequent complexation with the plasmid pCMVluc greatly increased luciferase expression in epithelial and lymphocytic cell lines above that obtained with plain lipoplexes. The percentage of cells transfected also increased by an order of magnitude. The zeta potential of the ternary complexes was lower than that of the lipoplexes. Transfection activity by HSA-lipoplexes was not inhibited by up to 30% serum. The combined use of HSA and a pH-sensitive peptide resulted in significant gene expression in human primary macrophages. HSA-lipoplexes mediated significantly higher gene expression than plain lipoplexes or naked DNA in the lungs and spleen of mice. Our results indicate that negatively charged HSA-lipoplexes can facilitate efficient transfection of cultured cells, and that they may overcome some of the problems associated with the use of highly positively charged complexes for gene delivery in vivo.