Polycationic Carriers Research Articles

Multimerized siRNA Cross-linked by Gold Nanoparticles

In this study, siRNAs terminated with thiol groups were multimerized and cross-linked using ∼5 nm gold nanoparticles (AuNPs) via Au-S chemisorption that can be intracellularly reduced. AuNPs immobilized with single-stranded antisense siRNA were assembled with those with single-stranded sense siRNA via complementary hybridization or assembled with those with single-stranded dimeric sense siRNA. The multimerized siRNA cross-linked by AuNPs showed increased charge density and enhanced enzymatic stability, and exhibited good complexation behaviors with a polycationic carrier, linear polyethylenimine (L-PEI). The resultant multi-siRNA/AuNPs/L-PEI polyelectrolyte complexes exhibited far greater gene silencing efficiencies of green fluorescent protein (GFP) and vascular endothelial growth factor (VEGF) compared to naked siRNA complexes. They could also be visualized by micro-CT imaging. The results suggest that AuNP-mediated multimerization of siRNAs could be a rational approach to achieve both gene silencing and imaging at a target tissue simultaneously.

Cationic Lipid-Coated Gold Nanoparticles as Efficient and Non-Cytotoxic Intracellular siRNA Delivery Vehicles

Cationic lipid-coated gold nanoparticles were developed for efficient intracellular delivery of therapeutic siRNA. Particle formation was characterized by UV-visible spectroscopy, atomic force microscopy, and dynamic light scattering analysis. Cellular uptake, gene silencing effect, and cytotoxicity were investigated in multiple human cancer cell lines. Nanoparticles had a spherical nanostructure with highly cationic surface charge and could form stable nanosized polyelectrolyte complexes with siRNA via electrostatic interactions; complexes exhibited efficient intracellular uptake and significant gene silencing effect with markedly low cytotoxicity compared to the widely used polycationic carrier, linear polyethyleneimine. We demonstrated that cationic lipid-coated gold nanoparticles could be widely utilized as efficient and safe siRNA nanocarriers for diverse therapeutic and diagnostic applications.

Unconventional internalization mechanisms underlying functional delivery of antisense oligonucleotides via cationic lipoplexes and polyplexes

There is mounting interest in developing antisense and siRNA oligonucleotides into therapeutic entities; however, this potential has been limited by poor access of oligonucleotides to their pharmacological targets within cells. Transfection reagents, such as cationic lipids and polymers, are commonly utilized to improve functional delivery of nucleic acids including oligonucleotides. Cellular entry of large plasmid DNA molecules with the assistance of these polycationic carriers is mediated by some form of endocytosis; however, the mechanism for delivery of small oligonucleotide molecules has not been well established. In this study, splice-shifting oligonucleotides have been formulated into cationic lipoplexes and polyplexes, and their internalization mechanisms have been examined by using pharmacological and genetic inhibitors of endocytosis. The results showed that intercellular distribution of the oligonucleotides to the nucleus governs their pharmacological response. A mechanistic study revealed that oligonucleotides delivered by lipoplexes enter the cells partially by membrane fusion and this mechanism accounts for the functional induction of the target gene. In contrast, polyplexes are internalized by unconventional endocytosis pathways that do not require dynamin or caveolin. These studies may help rationally design novel delivery systems with superior transfection efficiency but lower toxicity.

Structure, Dynamics, and Energetics of siRNA−Cationic Vector Complexation: A Molecular Dynamics Study

The design and synthesis of safe and efficient nonviral vectors for gene delivery has attracted significant attention in recent years. Previous experiments have revealed that the charge density of a polycation (the carrier) plays a crucial role in complexation and the release of the gene from the complex in the cytosol. In this work, we adopt an atomistic molecular dynamics simulation approach to study the complexation of short strand duplex RNA with six cationic carrier systems of varying charge and surface topology. The simulations reveal detailed molecular-level pictures of the structures and dynamics of the RNA-polycation complexes. Estimates for the binding free energy indicate that electrostatic contributions are dominant followed by van der Waals interactions. The binding free energy between the 8(+)polymers and the RNA is found to be larger than that of the 4(+)polymers, in general agreement with previously published data. Because reliable binding free energies provide an effective index of the ability of the polycationic carrier to bind the nucleic acid and also carry implications for the process of gene release within the cytosol, these novel simulations have the potential to provide us with a much better understanding of key mechanistic aspects of gene-polycation complexation and thereby advance the rational design of nonviral gene delivery systems.

Prostate cancer cell–specific VEGF siRNA delivery system using cell targeting peptide conjugated polyplexes

A polymeric gene carrier was developed to deliver vascular endothelial growth factor (VEGF) small interfering RNA (siRNA) for prostate cancer cells in a target-specific manner. Prostate cancer–binding peptide (PCP) was conjugated with polyethylenimine (PEI) via a poly(ethylene glycol) (PEG) linker (PEI–PEG–PCP). The PEI–PEG–PCP conjugate could effectively condense siRNA to form stable polyelectrolyte complexes (polyplexes) with an average diameter of approximately 150 nm in an aqueous solution. VEGF siRNA/PEI–PEG–PCP polyplexes exhibited significantly higher VEGF inhibition efficiency than PCP-unmodified polycationic carriers (PEI–PEG or PEI) in human prostate carcinoma cells (PC-3 cells). The enhanced gene silencing activity of VEGF siRNA/PEI–PEG–PCP was maintained even under serum conditions, owing to the steric stabilization of the polyplexes with hydrophilic PEG grafts. Confocal microscopic studies revealed that the siRNA/PEI–PEG–PCP polyplexes were delivered into PC-3 cells in a PCP ligand–specific manner.

A dimethylmaleic acid–melittin‐polylysine conjugate with reduced toxicity, pH‐triggered endosomolytic activity and enhanced gene transfer potential

Poor endosomal release is one major barrier of gene delivery. Endosomolytic polyethylenimine-melittin conjugates have shown to enhance gene transfer efficiency; however, cytotoxicity due to their general membrane-destabilizing properties limits their application. To overcome this drawback we grafted a polycation with a masked pH-responsive melittin derivate and investigated lytic activity, gene transfer efficiency and cytotoxicity of the resulting conjugate. Melittin (Mel) was modified with dimethylmaleic anhydride (DMMAn) and covalently coupled to poly-L-lysine (PLL). The membrane lytic activity was analyzed after incubation at neutral or endosomal pH. PLL-DMMAn-Mel polyplexes were generated in HEPES-buffered glucose and tested in transfection experiments using luciferase as reporter gene. Cellular cytotoxicity was analyzed by measurement of membrane integrity and metabolic activity. Covalent attachment of DMMAn-modified melittin to PLL resulted in a pH-responsive conjugate. No lytic activity was observed at neutral pH; after acidic cleavage of the protecting groups at pH 5 lytic activity was regained. Acute toxicity was greatly reduced (as compared to PLL-Mel or even unmodified PLL) and high gene expression levels (up to 1800-fold higher than unmodified PLL) were obtained. Modification of the polycationic carrier PLL with DMMAn-masked melittin not only enhances gene transfer efficiency, but also strongly reduces the acute toxicity of melittin and PLL. Hence this modification might be useful for optimizing polycationic gene carriers.

Structure and Design of Polycationic Carriers For Gene Delivery

The development of safe and effective gene delivery methods is a major challenge to enable gene therapy or DNA vaccines to become a reality. Currently there are two major approaches for delivery of genetic material, viral and non-viral. The majority of on-going clinical trials in gene therapy or DNA vaccines use retroviruses and adenoviruses for delivering genetic materials. Viral delivery systems are far more effective than non-viral delivery however there are concerns regarding toxicity, immunogenicity and possible integration of viral genetic material into the human genome. Given the negative charge of the phosphate backbone of DNA, polycationic molecules have been the major focus as carriers of DNA. There are several physiological barriers to overcome for effective systemic delivery of DNA. The ideal vector must be stable in the systemic circulation, escape the reticuloendothelial system, able to extravasate tissues, enter the target cell, escape lysosomal degradation and transport DNA to the nucleus to be transcribed. With increasing understanding of the physicochemical properties essential to overcome the various barriers, it is possible to apply rational design to the cationic carriers. A number of poly-amino acids, cationic block co-polymers, dendrimers and cyclodextrins have been rationally designed to optimize gene delivery. This review will discuss approaches that have been used to design various synthetic polycations with enhanced DNA condensing ability, serum stability and endosomolytic capability for efficient gene transfer in vitro and in vivo.

197. Development of Chitosan Nanoparticles for Gene Delivery System

Chitosan has been developed as a polycationic carrier for pDNA in gene delivery system with promising results. On the other hand, the mechanism of the intracellular transport of pDNA/chitosan complexes remains rudimentary yet. In this study, microinjection method was employed to investigate it. The effect of pDNA concentration, post-injection time, cell cycle and stoichiometry of pDNA/chitosan complexes on expression efficiency were investigated. Stability of pDNA complexes in cytosol was also estimated.

Intelligent polymers as nonviral vectors

The successful gene therapy largely depends on the vector type that allows a selective and efficient gene delivery to target cells with minimal toxicity. Nonviral vectors are much safer and cheaper, can be produced easily in large quantities, and have higher genetic material carrying capacity. However, they are generally less efficient in delivering DNA and initiating gene expression as compared to viral vectors, particularly when used in vivo. As nonviral vectors, polycations may work well for efficient cell uptake and endosomal escape, because they do form compact and smaller complexes with plasmid DNA and carry amine groups, which give positive charge and buffering ability that allows safe escape from endosome/lysosome. However, this is a disadvantage in the following step, which is releasing the plasmid DNA within the cytosol. In order to initiate transcription and enhance gene expression, the polymer/plasmid complex should dissociate after releasing from endosome safely and effectively. There are also other limitations with some of the polycationic carriers, for example, aggregation, toxicity, etc. Intelligent polymers, also called as 'stimuli responsive polymers', have a great potential as nonviral vectors to obtain site-, timing-, and duration period-specific gene expression, which is already exhibited in recent studies that are briefly summarized here.

Complexes of Plasmid DNA with Basic Domain 47-57 of the HIV-1 Tat Protein Are Transferred to Mammalian Cells by Endocytosis-mediated Pathways

Arginine-rich peptides, penetratins, as part of a number of cellular and viral proteins, can penetrate across plasma membrane directly, without participation of endocytosis. We show that one of penetratins, the basic domain 47-57 of human immunodeficiency virus, type 1, transcription factor Tat (Tat peptide), is able to interact with plasmid DNA electrostatically. These interactions result in formation of polyelectrolytic complexes at various negative/positive charge ratios of plasmid DNA and Tat peptide. Plasmid DNA is capable of binding to Tat peptide up to 1.7-fold excess of the complex positive charge. The DNA-Tat complexes can be used for delivery of plasmid DNA into mammalian cells. Transfection efficacy of cultured cells by DNA-Tat complexes is stimulated by free Tat peptide, most likely because it protects DNA-Tat complexes from disruption by anionic proteoglycans of cellular surface. Our data strongly argue in favor of the endocytosis-dependent mechanism of DNA-Tat complex uptake by mammalian cells similarly to internalization of complexes of plasmid DNA with other polycationic carriers. Moreover, different cell lines use different endocytosis-mediated pathways for DNA-Tat complex internalization. Intravenous injections to mice of DNA-Tat complexes in comparison with injections of naked DNA showed an inhibitory effect of DNA-Tat complex positive charge on expression of transferred gene. A low level of foreign gene expression in the liver of mice injected intravenously with positively charged DNA-Tat complexes is accounted for by inactivation of DNA-Tat complexes in the bloodstream due to their interactions with serum albumin. These data should be taken into account in an attempt to develop versatile gene delivery systems based on penetratin application for human disease therapy.

Stability of polycationic complexes of an antisense oligonucleotide in rat small intestine homogenates

Presystemic degradation in the gastrointestinal tract is one of the major problems contributing to the poor oral absorption of antisense oligonucleotides. Complexes between the antisense phosphorothioate oligodeoxynucleotide ISIS 2302 and the polycationic carriers protamine sulfate grade X, protamine chloride grade V, protamine phosphate grade X, poly- l-lysine hydrobromide (PLL), spermidine phosphate salt, spermine diphosphate salt, and Protasan™ G113 and CL113 were formulated in order to increase stability against intestinal nucleolytic degradation. Specific conductivity measurements were carried out to determine the charge ratio of the complex systems. Nuclease stability assays were performed in a rat small intestine homogenate model, which displayed significant exo- and endonuclease activity. Full-length oligonucleotide and metabolites were analyzed by capillary gel electrophoresis with UV detection at 260 nm. Most of the complexes of ISIS 2302 and the polycationic materials, except PLL-based systems, showed a better protection against enzymatic metabolism than free oligonucleotide. Protamine sulfate and protamine chloride considerably enhanced the nuclease stability of the phosphorothioate antisense oligonucleotide. The association of oligonucleotides with several polycationic substances proved to be an alternative to chemical modification in order to stabilize oligonucleotides in the gastrointestinal tract against nucleolytic degradation.

Methotrexate conjugate with branched polypeptide influences Leishmania donovani infection in vitro and in experimental animals.

Methotrexate (MTX) has been coupled to various structurally related, polycationic (poly[Lys(DL-Ala(m))] (AK), poly[Lys(Ser(i)-DL-Ala(m))] (SAK), poly[Lys(DL-Ala(m)-Leu(i))] (ALK)), or amphoteric (poly[Lys(Glu(i)-DL-Ala(m))] (EAK)) synthetic branched polypeptides containing poly[L-Lys] backbone by the aid of BOP reagent. The average degree of MTX incorporation was found to be dependent on the charge properties of the polymer. Under the experimental conditions used, the molar substitution ratio achieved was higher for polycations (25%) than for the amphoteric polypeptide (10%). We have studied the effect of polycationic polypeptides on Leishmania donovani infection. Results demonstrated that MTX conjugates in which the drug is covalently attached to carrier have pronounced leishmanicid activity. In this communication we showed that (a) a branched polypeptide-methotrexate conjugate with a polycationic carrier (ALK) increases the effect of MTX against Leishmania donovani infection in mice; (b) the covalent bond between the carrier and methotrexate is essential for both in vivo and in vitro activity; and (c) the number of Leishmania donovani parasites in infected macrophages are markedly reduced in conjugate treated animals. In vitro observation might also indicate that the MTX conjugate exhibits an effect through an uptake by macrophages which is different from that of the free drug.

Nonviral Vectors for In Vivo Gene Delivery: Physicochemical and Pharmacokinetic Considerations

The use of nonviral vectors is an attractive in vivo gene delivery strategy that is simpler than, and lacks some risks inherent in, viral systems. Liposomes and receptor-mediated polycation systems are promising carriers for delivery and expression of plasmid DNA encoding genes into the target cells. Many barriers need to be overcome for successful in vivo DNA delivery using these carrier systems. Such factors as extent of DNA condensation, particle size of the DNA complex, route of administration, stability against nucleases, target sites, in vivo disposition, binding to cell surface receptor and internalization, and intracellular trafficking affect in vivo gene delivery and expression. This review will provide a critical discussion of the merits and limitations of liposomal and polycationic carrier systems for gene transfer from the viewpoints of their physicochemical and pharmacokinetic properties.

Disposition of Positively Charged Bowman–Birk Protease Inhibitor Conjugates in Mice: Influence of Protein Conjugate Charge Density and Size on Lung Targeting

The influence of conjugate charge density and size on the targeting of cationic Bowman–Birk inhibitor (BBI) conjugates to the lungs was studied in mice. The biodistribution of BBI, either as the native protein or in the conjugated form (conjugated to a dicationic, tetracationic, or polycationic carrier), indicated that by increasing the charge density of BBI conjugates, the lung accumulation of the conjugates administered intravenously (iv) can be increased. The order of lung accumulation in these studies was as follows: polycationic‐ > tetracationic‐ > dicationic‐conjugated BBI > BBI. The influence of conjugate size on lung accumulation was studied in three experiments. First, the biodistribution of poly(D‐lysine) carriers of equal charge density but different molecular weight demonstrated that lung accumulation of polycationic carriers increases with an increase in carrier size. Second, the biodistributions of BBI, tyramine‐derivatized poly(D‐lysine)3kDa, and poly(D‐lysine)3kDaconjugated to BBI indicated that an increase in conjugate size alone is not sufficient to promote the lung accumulation of cationic BBI conjugates. Finally, the biodistribution poly(D‐lysine) complexed with heparin showed that targeting of a conjugate to the lungs can be abolished by neutralizing the charge on the carrier. Collectively, data in this paper demonstrate that the carrier‐mediated targeting of BBI to the lungs is dependent on (a) cationization of BBI, (b) the conjugate positive charge density, and (c) the size of the cationic conjugate if the charge density is maintained. Also, the data show that the size of the conjugate alone does not make a significant impact on lung accumulation.

Poly(L-lysine) has different membrane transport and drug-carrier properties when complexed with heparin.

Methotrexate (MTX) conjugated to a Mr 3000 poly(L-Lys) markedly inhibits the growth of Pro-3 MtxRII5-3 Chinese hamster ovarian cells, a mutant line known to be drug resistant because of defective MTX transport. In these cells, membrane transport of [3H]MTX-poly(Lys) is sharply decreased by addition of 0.5- to 2.5-fold heparin but remains at 15-20% of control in 2.5- to 50-fold heparin excess. Heparin addition at first markedly inhibits but, at high concentration, restores the growth inhibitory effect of MTX-poly(Lys). In excess heparin, MTX-poly(Lys) is transported as a heparin complex. Because reduced transport (15-20%) is sufficient to cause a 90% inhibition of cell growth, MTX-poly(Lys) apparently gains pharmacologic potency when compared to heparin. This gain can be related to a greater inhibitory effect on dihydrofolate reductase and to a different mode of transport. The inhibitory effect of MTX-poly(Lys) on dihydrofolate reductase in vitro is increased nearly 100-fold in the presence of excess heparin but remains less than that of free MTX. Unlike that of MTX-poly(Lys), the transport of MTX-poly(Lys)-heparin has the characteristics and efficiency of a receptor-mediated process. It proceeds by endocytosis but is not, as in the case of uncomplexed conjugate, followed by the intracellular generation of pharmacologically active breakdown products that would account for cytotoxicity. These observations raise the possibility that at least part of the MTX-poly(Lys)-heparin reaches cellular dihydrofolate reductase in the form of macromolecular complexes that escape from entrapment in endocytotic structures. Our data illustrate a way to overcome drug resistance by taking advantage of the specific uptake of a macromolecular drug carrier. They offer a method of drug delivery in which heparin improves selectivity and decreases the unwanted toxicity inherent to polycationic carriers.

Interaction of methotrexate with polycationic carriers

Binding parameters were measured for the in vitro interaction of methotrexate with poly-L-lysine and diethylaminoethyl dextran. The complexes were found to have apparent affinity constants of 2590 and 440 M −1 respectively at 37°, ionic strength 0.02. For hypotonic solutions containing therapeutic concentrations of methotrexate, this results in 87% binding of the drug to poly-L-lysine and 74% to diethylaminoethyl dextran. While the binding decreased to about 50% upon increasing ionic strength to physiologic levels, sufficient drug-carrying capacity was retained at isotonicity to support the potential utility of such complexes as tissue-specific drug carriers.