Effects of trehalose polycation end-group functionalization on plasmid DNA uptake and transfection

In this study, we have synthesized six analogs of a trehalose-pentaethylenehexamine glycopolymer (Tr4) that contain (1A) adamantane, (1B) carboxy, (1C) alkynyl-oligoethyleneamine, (1D) azido trehalose, (1E) octyl, or (1F) oligoethyleneamine end groups and evaluated the effects of polymer end group chemistry on the ability of these systems to bind, compact, and deliver pDNA to cultured HeLa cells. The polymers were synthesized in one-pot azide-alkyne cycloaddition reactions with an adaptation of the Carothers equation for step-growth polymerization to produce a series of polymers with similar degrees of polymerization. An excess of end-capping monomer was added at the end of the polymerizations to maximize functionalization efficiency, which was evaluated with GPC, NMR, and MALDI-TOF. The polymers were all found to bind and compact pDNA at similarly low N/P ratios and form polyplexes with plasmid DNA. The effects of the different end group structures were most evident in the polyplex internalization and transfection assays in the presence of serum as determined by flow cytometry and luciferase gene expression, respectively. The Tr4 polymers end-capped with carboxyl groups (1B) (N/P = 7), octyne (1E) (N/P = 7), and oligoethyleneamine (1F) (N/P = 7), were taken into cells as polyplex and exhibited the highest levels of fluorescence, resulting from labeled plasmid. Similarly, the polymers end-functionalized with carboxyl groups (1E at N/P = 7), octyl groups (1E at N/P = 15), and in particular oligoethyleneamine groups (1F at N/P = 15) yielded dramatically higher reporter gene expression in the presence of serum. This study yields insight into how very subtle structural changes in polymer chemistry, such as end groups can yield very significant differences in the biological delivery efficiency and transgene expression of polymers used for pDNA delivery.     

Protein-polymer nanoparticles for nonviral gene delivery

Protein-polymer conjugates were investigated as nonviral gene delivery vectors. BSA-poly(dimethylamino) ethyl methacrylate (PDMA) nanoparticles (nBSA) were synthesized using in situ atom transfer radical polymerization (in situ ATRP) and BSA as a macroinitiator. The diameter and charge of nBSA was a function of the ATRP reaction time and ranged from 5 to 15 nm and +8.9 to +22.5, respectively. nBSA were able to condense plasmid DNA (pDNA) and form polyplexes with an average diameter of 50 nm. nBSA/pDNA polyplexes transfected cells with similar efficiencies or better as compared to linear and branched PEI. Interestingly, the nBSA particle diameter and charge did not affect pDNA complexation and transgene expression, indicating that the same gene delivery efficiency can be achieved with lower charge ratios. We believe that with the use of protein-polymer conjugates additional functionality could be introduced to polyplexes by using different protein cores and, thus, they pose an interesting alternative to the design of nonviral gene delivery vectors.     

General structure-activity relationship for poly(glycoamidoamine)s: the effect of amine density on cytotoxicity and DNA delivery efficiency

Herein, two new series of poly(glycoamidoamine)s (branched and linear) have been synthesized by polycondensation. The polymer repeat units have been designed to contain D-glucaramide, meso-galactaramide, D-mannaramide, or L-tartaramide structures and five or six ethyleneamine units to investigate the amine density effects on the bioactivity as compared to a similar series of poly(glycoamidoamine)s previously described that contain four ethyleneamines. These delivery vehicles were created to examine the effects that the number of secondary amines in the polymer repeat unit and the polymer structure (branched and linear) have on plasmid DNA (pDNA) binding affinity, polyplex formation, cell viability, and gene expression in the absence and presence of serum in the culture medium. The results reveal that the new polymers with higher amine density in the repeat unit do not significantly enhance the transfection efficiency compared to that of previous models containing four ethyleneamines, but an increase in cytotoxicity is noticed. Linear polymers reveal higher pDNA neutralization efficacy, gene expression, and toxicity than the branched versions containing a similar chemical structure, which may be caused by a higher protonation of the amine groups. With these new vectors, some interesting trends emerged. The galactaramide and tartaramide analogues revealed higher delivery efficiency than the glucaramide and mannaramide structures. In addition, the branched and linear structures containing five ethyleneamines in the repeat unit formed polyplexes at higher N/P ratios, which had lower zeta potential and lower delivery efficacy than the analogues with six ethyleneamines, and also the linear structures generally revealed higher delivery efficiency and toxicity when compared to those of their branched analogues.     

New class of polymers for the delivery of macromolecular therapeutics

Cationic polymers show promise for the in vitro and in vivo delivery of macromolecular therapeutics. Known cationic polymers, e.g., poly(L)lysine (PLL) and polyethylenimine (PEI), have been employed in native and modified forms for the delivery of plasmid DNA (pDNA) and reveal varying levels of toxicity. Here, we report the preparation of a new class of cationic polymers that are specifically designed to deliver macromolecular therapeutics. Linear, cationic, beta-cyclodextrin (beta-CD)-containing polymers (CD-polymers) are synthesized by copolymerizing difunctionalized beta-CD monomers (AA) with other difunctionalized comonomers (BB) such that an AABBAABB product is formed. The beta-CD polymers are able to bind approximately 5 kbp pDNA above polymer to DNA (+/-) charge ratios of 1.5, compact the bound pDNA into particles of approximately 100-150 nm in size at charge ratios above 5+/-, and transfect cultured cells at charge ratios above 10+/-. In vitro transfections with the new beta-CD-polymers are comparable to the best results obtained in our hands with PEI and Lipofectamine. Some cell line-dependent toxicities are observed for serum-free transfections; however, no toxicity is revealed at charge ratios as high as 70+/- in transfections conducted in 10% serum. Single IV and IP doses as high as 200 mg/kg in mice showed no mortalities.     

Nanostructure of polyplexes formed between cationic diblock copolymer and antisense oligodeoxynucleotide and its influence on cell transfection efficiency

Although various cationic polymers have been used to condense anionically charged DNA to improve their transfection efficiency, there is still a lack of fundamental understanding about how to control the nanostructure and charge of the polyplexes formed and how to relate such information to cell transfection efficiency. In this work, we have synthesized a weak cationic and phosphorylcholine-containing diblock copolymer and used it as a model vector to deliver an antisense oligodeoxynucleotide (ODN) into HeLa cells. Small angle neutron scattering (SANS) was used to determine the copolymer/ODN polyplex structure. The SANS data revealed the formation of polyplex nanocylinders at high copolymer (N)/ODN (P) charge ratios, where N symbolizes the amine groups on the copolymer and P symbolizes the phosphate groups. However, the cylindrical lengths remained constant, indicating that the ODN binding over this region did not alter the cylindrical shape of the copolymer in solution. As the N/P ratio decreased and became close to unity the polyplex diameters remained constant, but their lengths increased substantially, suggesting the end-to-end bridging by ODN binding between copolymer cylinders. As the N/P ratios went below unity (with ODN in excess), the polyplex diameters increased substantially, indicating different ODN bridging to bundle the small polyplexes together. Transfection studies from HeLa cells indicated a steady increase in transfection efficiency with increasing cationic charge and decreasing polyplex size. Cell growth inhibition assay showed significant growth inhibition by the polyplexes coupled with weak cytotoxicity, indicating effective ODN delivery. While this study has confirmed the overall charge effect, it has also revealed progressive structural changes of the polyplexes against varying charge ratio, thereby providing useful insight into the mechanistic process behind the ODN delivery.     

Galactose-poly(ethylene glycol)-polyethylenimine for improved lung gene transfer

Polyethylenimine (PEI) is a potential gene transfer agent, but is limited by its poor transfection efficiency in vivo due to poor solubility and stability, pronounced toxicity and non-specific interaction with target cells. To improve its pulmonary gene transfection property, galactose (whose binding lectins are abundantly expressed in the lung) was selected as a ligand to improve the binding and uptake of the modified PEI/pDNA (plasmid DNA) polyplexes into lung cells. A novel protocol was developed to synthesize galactose-polyethylenglycol (PEG)-PEI copolymers. The resulting galactose-PEG-PEI/pDNA polyplexes showed improved solubility, stability, and reduced toxicity. Compared with that obtained by PEI/pDNA at a N/P ratio of 6, the transfection efficiency of 1% galactose-PEG-PEI/pDNA polyplexes at the N/P ratio of 36 was 4.5- and 11.6-fold in the A549 cell line and in mice lung, respectively. These data taken suggest that galactose-PEG-PEI may be a promising pulmonary gene delivery system.     

Enhancement of star vector-based gene delivery to endothelial cells by addition of RGD-peptide

This study aimed to investigate the feasibility of using a cationic nonviral gene carrier in endothelial cells for enhancing gene expression by the addition of an integrin-binding RGD peptide. A 4-branched cationic polymer of poly( N,N-dimethylaminopropylacrylamide) (star vector), developed as a gene carrier, could complex with the luciferase-encoding plasmid DNA under a charge ratio of 5 (vector/pDNA) to form polymer/DNA complexes (polyplexes). The addition of the RGD-containing peptide (GRGDNP) to the polyplex solution led to a decrease in the zeta-potential from ca. +30 to +20 mV along with the reduction in the particle size from ca. 300 to 200 nm. Additionally, a marked inhibition of polyplex aggregation was observed, indicating the coating of the polyplex surface with RGD peptides. A transfection study on endothelial cells showed that the luciferase activity increased with the amount of RGD peptides added to the polyplexes and exhibited minimal cellular cytotoxicity. The transfection activity further increased when cyclic RGD peptides (RGDFV) were used; the activity with RGD peptide addition was approximately 8-fold compared to that without RGD peptide addition. Gene delivery to endothelial cells was significantly enhanced by only the addition of RGD peptides to star vector-based polyplexes.     

Reducible poly(amido ethylenimine)s designed for triggered intracellular gene delivery

Poly(amido ethylenimine) polymers, a new type of peptidomimetic polymer, containing multiple disulfide bonds (SS-PAEIs) designed to degrade after delivery of plasmid DNA (pDNA) into the cell were synthesized and investigated as new carriers for triggered intracellular gene delivery. More specifically, three SS-PAEIs were synthesized from Michael addition reactions between cystamine bisacrylamide (CBA) and three different ethylene amine monomers, i.e., ethylenediamine (EDA), diethylenetriamine (DETA), or triethylenetetramine (TETA). Complete addition reactions were confirmed by (1)H NMR. The molecular weight, buffer capacity, and relative degree of branching for each SS-PAEI was determined by gel permeation chromatography (GPC), acid-base titration, and liquid chromatography-mass spectroscopy (LC-MS), respectively. Physicochemical characteristics of polymer/pDNA complexes (polyplexes) were analyzed by gel electrophoresis, particle size, and zeta-potential measurements. All three SS-PAEIs effectively complex pDNA to form nanoparticles with diameters less than 200 nm and positive surface charges of approximately 32 mV. The in vitro gene transfer properties of SS-PAEIs were evaluated using mouse embryonic fibroblast cell (NIH3T3), primary bovine aortic endothelial cell (BAEC), and rat aortic smooth muscle cell (A7R5) lines. Interestingly, polyplexes based on all three SS-PAEIs exhibited remarkably high levels of reporter gene expression with nearly 20x higher transfection efficiency than polyethylenimine 25k. The high transfection efficiency was maintained in the presence of 10% serum in the transfection medium. Furthermore, confocal microscopy experiments using labeled pDNA indicated that polyplexes of SS-PAEI displayed greater intracellular distribution of pDNA as compared to PEI, most likely due to environmentally triggered release. Therefore, SS-PAEIs are a new class of transfection agents that facilitate high gene expression while maintaining a low level of toxicity.     

PEGylation of poly(ethylene imine) affects stability of complexes with plasmid DNA under in vivo conditions in a dose-dependent manner after intravenous injection into mice

The influence of PEGylation on polyplex stability from poly(ethylene imine), PEI, and plasmid DNA was investigated both in vitro and after intravenous administration in mice. Polyplexes were characterized with respect to particle size (dynamic light scattering), zeta-potential (laser Doppler anemometry), and morphology (atomic force microscopy). Pharmacokinetics and organ accumulation of both polymers and pDNA were investigated using 125I and 32P radioactive labels, respectively. Furthermore gene expression patterns after 48 h were measured in mice. To elucidate the effect of different doses, all experiments were performed using ca. 1.5 microg and 25 microg of pDNA per mouse. Our studies demonstrated that both PEI and PEG-PEI form stable polyplexes with DNA with similar sizes of 100-130 nm. The zeta potential of PEI/pDNA polyplexes was highly positive, whereas PEG-PEI/pDNA showed a neutral surface charge as expected. The pharmacokinetic and organ distribution profiles after 2 h show similarities for both PEI and pDNA blood-level time curves from polyplexes at both doses indicative for significant stability in the bloodstream. A very rapid clearance from the bloodstream was observed and as major organs of accumulation liver and spleen were identified. PEG-PEI/pDNA complexes at a dose of approximately 25 microg exhibit similar profiles except a significantly lower deposition in the lung. At the lower dose of approximately 1.5 microg pDNA, however, for polyplexes from PEG-PEI, significant differences in blood level curves and organ accumulation of polymer and pDNA were found. In this case PEG-PEI shows a greatly enhanced circulation time in the bloodstream. By contrast, pDNA was rapidly cleared from circulation and significant amounts of radioactivity were found in the urine, suggesting a rapid degradation possibly by serum nucleases after complex separation. Regarding in vivo gene expression, no luciferase expression could be detected at approximately 1.5 microg dose in any organ using both types of complexes. At 25 microg only in the case of PEI/pDNA complexes were significant levels of the reporter gene detected in lung, liver, and spleen. This coincided with high initial accumulation of pDNA complexed with PEI and a high acute in vivo toxicity. For PEG-PEI, initial accumulation was much lower and no gene expression as well as a low acute toxicity was found. In summary, our data demonstrate that PEG-PEI used in this study is not suitable for low dose gene delivery. At a higher dose of approximately 25 microg, however, polyplex stability is similar to PEI/pDNA combined with a more favorable organ deposition and significantly lower acute in vivo toxicity. These findings have consequences for the design of PEG-PEI-based gene delivery systems for in vivo application.     

Synthesis and in vitro evaluation of novel star-shaped block copolymers (blocked star vectors) for efficient gene delivery

Novel 4-branched diblock copolymers consisting of cationic chains as an inner domain and nonionic chains as an outer domain were prepared by iniferter-based living radial polymerization and evaluated as a polymeric transfectant. The cationic polymerization of 3-(N,N-dimethylamino)propyl acrylamide (DMAPAAm) using 1,2,4,5-tetrakis( N,N-diethyldithiocarbamylmethyl)benzene as a 4-functional iniferter followed by the nonionic block polymerization of N,N-dimethylacrylamide (DMAAm) afforded 4-branched diblock copolymers with controlled compositions. By changing the solution or irradiation conditions, 4-branched PDMAPAAms with molecular weights of 10,000, 20,000, and 50,000 were synthesized. In addition, by graft polymerization, PDMAPAAm-PDMAAm blocked copolymers with copolymer composition (unit ratio of DMAAm/DMAPAAm) ranging from 0.18 to 1.0 for each cationic polymer were synthesized. All polymers were shown to interact with and condense plasmid DNA to yield polymer/DNA complexes (polyplexes). A transfection study on COS-1 cells showed that the polyplexes from block copolymers with cationic chain length of approximately 50,000 and a nonionic chain length of 30,000, which were approximately 200 nm in diameter and very stable in aqueous media, had the most efficient luciferase activity with minimal cellular cytotoxicity under a charge ratio of 20 (vector/pDNA). The PDMAPAAm-PDMAAm-blocked, star-shaped polymers are an attractive novel class of nonviral gene delivery systems.     

Phosphonium-containing diblock copolymers for enhanced colloidal stability and efficient nucleic Acid delivery

RAFT polymerization successfully controlled the synthesis of phosphonium-based AB diblock copolymers for nonviral gene delivery. A stabilizing block of either oligo(ethylene glycol(9)) methyl ether methacrylate or 2-(methacryloxy)ethyl phosphorylcholine provided colloidal stability, and the phosphonium-containing cationic block of 4-vinylbenzyltributylphosphonium chloride induced electrostatic nucleic acid complexation. RAFT polymerization generated well-defined stabilizing blocks (M(n) = 25000 g/mol) and subsequent chain extension synthesized diblock copolymers with DPs of 25, 50, and 75 for the phosphonium-containing block. All diblock copolymers bound DNA efficiently at ± ratios of 1.0 in H(2)O, and polyplexes generated at ± ratios of 2.0 displayed hydrodynamic diameters between 100 and 200 nm. The resulting polyplexes exhibited excellent colloidal stability under physiological salt or serum conditions, and they maintained constant hydrodynamic diameters over 24 h. Cellular uptake studies using Cy5-labeled DNA confirmed reduced cellular uptake in COS-7 and HeLa cells and, consequently, resulted in low transfection in these cell lines. Serum transfection in HepaRG cells, which are a predictive cell line for in vivo transfection studies, showed successful transfection using all diblock copolymers with luciferase expression on the same order of magnitude as Jet-PEI. All diblock copolymers exhibited low cytotoxicity (>80% cell viability). Promising in vitro transfection and cytotoxicity results suggest future studies involving the in vivo applicability of these phosphonium-based diblock copolymer delivery vehicles.     

Phosphonium-containing polyelectrolytes for nonviral gene delivery

Nonviral gene therapy focuses intensely on nitrogen-containing macromolecules and lipids to condense and deliver DNA as a therapeutic for genetic human diseases. For the first time, DNA binding and gene transfection experiments compared phosphonium-containing macromolecules with their respective ammonium analogs. Conventional free radical polymerization of quaternized 4-vinylbenzyl chloride monomers afforded phosphonium- and ammonium-containing homopolymers for gene transfection experiments of HeLa cells. Aqueous size exclusion chromatography confirmed similar absolute molecular weights for all polyelectrolytes. DNA gel shift assays and luciferase expression assays revealed phosphonium-containing polymers bound DNA at lower charge ratios and displayed improved luciferase expression relative to the ammonium analogs. The triethyl-based vectors for both cations failed to transfect HeLa cells, whereas tributyl-based vectors successfully transfected HeLa cells similar to Superfect demonstrating the influence of the alkyl substituent lengths on the efficacy of the gene delivery vehicle. Cellular uptake of Cy5-labeled DNA highlighted successful cellular uptake of triethyl-based polyplexes, showing that intracellular mechanisms presumably prevented luciferase expression. Endocytic inhibition studies using genistein, methyl β-cyclodextrin, or amantadine demonstrated the caveolae-mediated pathway as the preferred cellular uptake mechanism for the delivery vehicles examined. Our studies demonstrated that changing the polymeric cation from ammonium to phosphonium enables an unexplored array of synthetic vectors for enhanced DNA binding and transfection that may transform the field of nonviral gene delivery.     

Poly[Lys-(AEDTP)]: a cationic polymer that allows dissociation of pDNA/cationic polymer complexes in a reductive medium and enhances polyfection.

Polyplexes of high stability resulting from the condensation of a plasmid DNA by a cationic polymer are widely used to develop polymer-based gene delivery systems. However, the plasmid must be released from its vector once inside the cells for an efficient expression of the exogenous gene in the cell nucleus. We have designed a disulfide-containing cationic polymer termed poly[Lys-(AEDTP)] which allowed for the formation of polyplexes and the release of the plasmid in a reductive medium. The amino groups of polylysine were substituted with 3-(2-aminoethyldithio)propionyl residues in order to have each amino group of poly[Lys-(AEDTP)] interacting with a phosphate DNA linked to the polymer backbone via a disulfide bond. As evidenced by agarose gel electrophoresis and ethidium bromide/pDNA fluorescence restoration, poly[Lys-(AEDTP)] polyplexes were decondensed and the plasmid released upon treatment with either dithiothreitol, glutathione in the presence of glutathione reductase, or the thioredoxin reductase. Electron microscopy showed that polyplexes exhibiting spherical particles of a mean size at about 100 nm were decondensed in the presence of glutathione and exhibited filamentous aggregates. Finally, we found that the transfection of 293T7 and HepG2 cells was 10- and 50-fold more efficient with poly[Lys-(AEDTP)] polyplexes, respectively, than with poly[Lys] polyplexes. These results indicate that disulfide-containing cationic polymers must be borne in mind for developing polymer-base gene delivery systems.     

Stabilization of poly-L-lysine/DNA polyplexes for in vivo gene delivery to the liver

We are developing a self-assembling non-viral in vivo gene delivery vehicle based on poly-l-lysine and plasmid DNA. We have characterized poly-l-lysines of different chain lengths for DNA condensation and strength of DNA binding. Poly-l-lysine chains >20 residues bound DNA efficiently in physiological saline, while shorter chains did not. Attachment of asialoorosomucoid to PLL increased the PLL chain length required for efficient DNA binding in saline and for efficient DNA condensation. By electron microscopy, poly-l-lysine/DNA polyplexes appeared as toroids 25-50 nm in diameter or rods 40-80 nm long; conjugation of asialoorosomucoid to the polylysine component increased the size of resulting polyplexes to 50-90 nm. In water, poly-l-lysine and asialoorosomucoid-PLL polyplexes have effective diameters of 46 and 87.6 nm, respectively. Polyplexes containing only poly-l-lysine and DNA aggregated in physiological saline at all charge ratios and aggregated at neutral charge ratios in water. Attachment of asialoorosomucoid lessened, but did not eliminate, the aggregation of PLL polyplexes, and did not result in efficient delivery of polyplexes to hepatocytes. Conjugation of polyethylene glycol to poly-l-lysine sterically stabilized resulting polyplexes at neutral charge ratios by shielding the surfaces. For efficient in vivo gene delivery, polyplexes will need to be sterically stabilized to prevent aggregation and interaction with serum components.     

Reduction-degradable linear cationic polymers as gene carriers prepared by Cu(I)-catalyzed azide-alkyne cycloaddition

Linear reduction-degradable cationic polymers with different secondary amine densities (S2 and S3) and their nonreducible counterparts (C2 and C3) were synthesized by Cu(I)-catalyzed azide-alkyne cycloaddition (CuAAC) step-growth polymerization of the dialkyne-oligoamine monomers and the diazide monomers. These polymers were studied with a goal of developing a set of new gene carriers. The buffering capacity and DNA binding ability of these polymers were evaluated by acid-base titration, gel retardation, and ethidium bromide (EB) exclusion assay. The polymers with lower amine density exhibit a weaker DNA-binding ability but a stronger buffering capacity in the range of pH 5.1 and 7.4. Particle size and zeta-potential measurements demonstrate that the polymers with higher amine density condense pDNA to form polyplexes with smaller sizes, while the disulfide bond in the backbone shows a negative effect on the condensing capability of the polymers, resulting in the formation of polyplexes with large size and nearly neutral surface. The reduction-sensitive polyplexes formed by polymer S2 or S3 can be disrupted by dithiothreitol (DTT) to release free DNA, which has been proven by the combination of gel retardation, EB exclusion assay, particles sizing, and zeta potential measurements. Cell viability measurements by MTT assay demonstrate that the reduction-degradable polymers (S2 and S3) have little cytotoxicity while the nonreducible polymers (C2 and C3) show obvious cytotoxicity, in particular, at high N/P ratios. In vitro transfection efficiencies of these polymers were evaluated using EGFP and luciferase plasmids as the reporter genes. Polymers S3 and S2 show much higher efficiencies than the nonreducible polymers C3 and C2 in the absence of 10% serum; unexpectedly, the lowest transfection efficiency has been observed for polymer S3 in the presence of serum.     

Poly(ethylene oxide) grafted with short polyethylenimine gives DNA polyplexes with superior colloidal stability, low cytotoxicity, and potent in vitro gene transfection under serum conditions

Poly(ethylene oxide) grafted with 1.8 kDa branched polyethylenimine (PEO-g-PEI) copolymers with varying compositions, that is, PEO(13k)-g-10PEI, PEO(24k)-g-10PEI, and PEO(13k)-g-22PEI, were prepared and investigated for in vitro nonviral gene transfer. Gel electrophoresis assays showed that PEO(13k)-g-10PEI, PEO(24k)-g-10PEI, and PEO(13k)-g-22PEI could completely inhibit DNA migration at an N/P ratio of 4/1, 4/1, and 3/1, respectively. Dynamic light scattering (DLS) and zeta potential measurements revealed that all three graft copolymers were able to effectively condense DNA into small-sized (80-245 nm) particles with moderate positive surface charges (+7.2 ～ +24.1 mV) at N/P ratios ranging from 5/1 to 40/1. The polyplex sizes and zeta-potentials intimately depended on PEO molecular weights and PEI graft densities. Notably, unlike 25 kDa PEI control, PEO-g-PEI polyplexes were stable against aggregation under physiological salt as well as 20% serum conditions due to the shielding effect of PEO. MTT assays in 293T cells demonstrated that PEO-g-PEI polyplexes had decreased cytotoxicity with increasing PEO molecular weights and decreasing PEI graft densities, wherein low cytotoxicities (cell viability >80%) were observed for polyplexes of PEO(13k)-g-22PEI, PEO(13k)-g-10PEI, and PEO(24k)-g-10PEI up to an N/P ratio of 20/1, 30/1, and 40/1, respectively. Interestingly, in vitro transfection results showed that PEO(13k)-g-10PEI polyplexes have the best transfection activity. For example, PEO(13k)-g-10PEI polyplexes formed at an N/P ratio of 20/1, which were essentially nontoxic (100% cell viability), displayed over 3- and 4-fold higher transfection efficiencies in 293T cells than 25 kDa PEI standard under serum-free and 10% serum conditions, respectively. Confocal laser scanning microscopy (CLSM) studies using Cy5-labeled DNA confirmed that these PEO-g-PEI copolymers could efficiently deliver DNA into the perinuclei region as well as into nuclei of 293T cells at an N/P ratio of 20/1 following 4 h transfection under 10% serum conditions. PEO-g-PEI polyplexes with superior colloidal stability, low cytotoxicity, and efficient transfection under serum conditions are highly promising for safe and efficient in vitro as well as in vivo gene transfection applications.     

Application of an HIV gp41-derived peptide for enhanced intracellular trafficking of synthetic gene and siRNA delivery vehicles

Endosomal release is an efficiency-limiting step for many nonviral gene delivery vehicles. In this work, nonviral gene delivery vehicles were modified with a membrane-lytic peptide taken from the endodomain of HIV gp41. Peptide was covalently linked to polyethylenimine (PEI) and the peptide-modified polymer was complexed with DNA. The resulting nanoparticles were shown to have similar physicochemical properties as complexes formed with unmodified PEI. The gp41-derived peptide demonstrated significant lytic activity both as free peptide and when conjugated to PEI. Significant increases in transgene expression were achieved in HeLa cells when compared to unmodified polyplexes at low polymer to DNA ratios. Additionally, peptide-modified polyplexes mediated significantly enhanced siRNA delivery compared to unmodified polyplexes. Despite increases in transgene expression and siRNA knockdown, there was no increase in internalization or binding of modified carriers as determined by flow cytometry. The hypothesis that the gp41-derived peptide increases the endosomal escape of vehicles is supported by confocal microscopy imaging of DNA distributions in transfected cells. This work demonstrates the use of a lytic peptide for improved trafficking of nonviral gene delivery vehicles.     

Pentalysine-grafted ROMP polymers for DNA complexation and delivery

Amphiphilic graft polymers, containing oligolysine groups pendent to a hydrophobic polycyclooctene backbone, were used to form polyplexes with plasmid DNA pZsGreen1-N1. These poly(cyclooctene- graft-pentalysine) structures were found to be effective transfection reagents for COS-1 and HeLa cells. In the case of polymer 1e (average degree of polymerization of 206), protein expression levels 48 h post-transfection were found to be comparable to, or better than, commercial transfection reagents jetPEI and SuperFect. With HeLa cells, GFP expression levels were better than Lipofectamine 2000. Of particular interest was the excellent cell viability seen in experiments with polyplexes formed from the pentalysine-grafted polymers. In the example of the highest molecular weight graft copolymer, polymer 1e, cell viability relative to untreated cells was 99% with COS-1 cells and 92% with HeLa cells in contrast to the commercial reagents, which gave 67-80% with COS-1 cells and 17-52% with HeLa cells. The effectiveness of these polyolefin- graft-pentalysine structures as DNA delivery vehicles is attributed to their amphiphilic nature and branched architecture.     

Biophysical and transfection studies of an amine-modified poly(vinyl alcohol) for gene delivery

Novel, multifunctional polymers remain an attractive objective for drug delivery, especially for hydrophilic macromolecular drugs candidates such as peptides, proteins, RNA, and DNA. To facilitate intracellular delivery of DNA, new amine-modified poly(vinyl alcohol)s (PVAs) were synthesized by a two-step process using carbonyl diimidazole activated diamines to produce PVAs with different degrees of amine substitution. The resulting polymers were characterized using NMR, thermogravimetric analysis (TGA), and gelpermation chromatography (GPC). Atomic force microscopy (AFM), dynamic light scattering photon correlation spectroscopy (PCS), and zeta-potential were used to investigate polyplexes of DNA with PVA copolymers. These studies suggest an influence of the polycation structure on the morphology of condensed DNA in polyplexes. Significant differences were observed by changing both the degrees of amine substitution and the structure of the PVA backbone, demonstrating that both electrostatic and hydrophobic interactions affect DNA condensation. DNA condensation measured by an ethidium bromide intercalation assay showed a higher degree of condensation with pDNA with increasing degrees of amine substitution and more hydrophobic functional groups. These findings are in line with transfection experiments, in which a good uptake of these polymer DNA complexes was noted, unfortunately, with little endosomal escape. Co-administration of chloroquine resulted in increased endosomal escape and higher transfection efficiencies, due to disruption of the endosomal membrane. In this study, the structural requirements for DNA complexation and condensation were characterized to provide a basis for rational design of nonviral gene delivery systems.     

Gene transfection of Toxoplasma gondii using PEI/DNA polyplexes

The purpose of this study was to explore the potential of using cationic polyethylenimine (PEI) to deliver green fluorescent protein (GFP) to protozoan parasite Toxoplasma gondii. PEI/DNA polyplexes were formed using branched PEI and pEGFP-N1 plasmid with various N/P ratios that ranged from 5 to 50. With the increment of N/P ratio, the average size of formed PEI/DNA polyplexes determined by dynamic light scattering analysis decreased from 306 to 203nm, while the surface charge of polyplexes obtained by zeta potential measurements increased from 20.2 to 36.7mV. Gene transfection efficiency modulated by N/P ratio was determined, indicating PEI/DNA polyplexes were capable of transfecting parasites. The maximal GFP expression was observed 8h post-transfection using N/P ratio of 30. To demonstrate the infectivity and potential use of GFP-expressing T. gondii, transfected parasites were inoculated to the monolayer of human foreskin fibroblast (HFF) cells. GFP-expressing tachyzoites were observed in intracellular milieu of the infected HFF cells one day after the infection. After 12-day culture, the bradyzoites expressing GFP within cysts were clearly visualized extracellularly. Our results revealed that PEI can be harnessed as an effective and inexpensive reagent to construct GFP-expressing T. gondii which has potential uses such as the study of interconversion stages and antimicrobial drug screening.