Gene transfer with modified polyethylenimines

Branched and linear polyethylenimines (PEIs) have proven to be efficient and versatile agents for gene delivery in vitro. In addition, systemic administration of positively charged DNA/PEI complexes results in significant reporter gene expression in lungs. However, re-targeting of complexes to organs other than the lung is hampered by non-specific interactions of polyplexes with blood components and non-target cells. Thus, despite considerable transfectional activity, the properties of PEIs need to be further improved. Therefore, various modifications of PEIs have been explored in recent years. For example, to increase the circulation half-life of the DNA complexes, the surface charge of the particles was shielded by grafting hydrophilic polymers such as polyethylene glycols (PEGs) onto their surface. Alternatively, incorporation of certain ligands into the DNA complexes also resulted in charge shielding even without PEGylation. Herein, I review the most recent PEI derivatives, with a special focus on PEGylated and targeted polymers.     

Poly-l-glutamic acid derivatives as multifunctional vectors for gene delivery. Part B. Biological evaluation

Cationic polymers, such as poly-l-lysine (pLL) and polyethyleneimine (pEI), are receiving growing attention as vectors for gene therapy. They form polyelectrolyte complexes with DNA, resulting in a reduced size of the DNA and an enhanced stability toward nucleases. The major disadvantages of using both polymers for in vivo purposes are their cytotoxicity and, in the case of pEI, the fact that it's not biodegradable. In this work, we investigated the interaction between a series of cationic, glutamic acid based polymers and red blood cells. The MTT test was used to investigate the cytotoxicity of the complexes. The ability of the polymers to stabilize DNA toward nucleases was investigated. Transfection studies were carried out on Cos-1 cells. The results from the haemolysis studies, the haemagglutination studies, and the MTT assay show that the polymers are substantially less toxic than pLL and pEI. The polymers are able to protect the DNA from digestion by DNase I. The transfection studies show that the polymer-DNA complexes are capable of transfecting cells, most of them with poor efficiency compared to pEI-DNA complexes.     

Mechanism of initiation of in vitro DNA synthesis by the immunopurified complex between yeast DNA polymerase I and DNA primase

The immunopurified yeast DNA-polymerase-I--DNA-primase complex synthesizes oligo(rA) and oligo(rG) molecules that are used as primer for replication of poly(dT) and poly(dC). Neither initiation nor DNA synthesis is observed with poly(dA) and poly(dI). Nitrocellulose-filter binding shows that the enzyme complex binds to deoxypyrimidine polymers, but not to deoxypurine polymers. Although the yeast complex initiates DNA synthesis on deoxypyrimidine homopolymers, it prefers to elongate pre-existing primer molecules rather than to initiate de novo DNA replication. The size of the oligo(rA) and oligo(rG) primer molecules has been determined by urea/polyacrylamide gel electrophoresis: longer oligoribonucleotides are synthesized when their utilization is prevented by omitting dNTP. An oligodeoxythymidylate template with a chain length as short as five residues can support oligo(rA) synthesis catalyzed by the yeast DNA-polymerase--DNA-primase complex and the size of the oligoribonucleotide products synthesized with oligodeoxythymidylate of differing chain length has also been determined. The mechanistic properties of the DNA-polymerase--DNA-primase complexes, purified from different eukaryotic organisms, appear to be very similar. The possible biological implication of the studies on the mechanism and specificity of initiation of DNA synthesis in a well-defined model template system has been discussed.     

Effect of polymer grafting density on silica nanoparticle toxicity

Nanoparticles are commonly engineered with a layer of polymers on the surface used to increase their stability and biocompatibility, as well as providing multifunctional properties. Formulating the nanoparticle size and surface properties with polymers directly affects the way these nanoparticles interact with a biological system. Many previous studies have emphasized the importance of nanoparticle size and surface charge in affecting their toxicity in cells. However, the potential weakness in many of these studies is that the polymer grafting densities on nanoparticles have been disregarded during toxicity evaluation. In the current study, we hypothesized that the density of polymers on nanoparticles will affect their toxicity to cells, especially for nanoparticle cores that are toxic themselves. To address this issue, we synthesized a range of RAFT (reversible addition fragmentation chain transfer) polymers bearing different surface charges and coated them onto silica nanoparticles (SiNPs) with different grafting densities. The in vitro cytotoxicity of these SiNPs was evaluated using the MTT (thiazolyl blue tetrazolium bromide) assay with Caco-2 cells. We found that neutral (biocompatible) polymers with a high grafting density on SiNPs were effective at protecting the cells from the toxicity of the silica core. High cellular toxicity was only observed for cationic polymer-SiNPs, while all other neutral and anionic polymer-SiNPs induced limited cellular toxicity. In contrast, the toxic effects induced by low density polymer-coated SiNPs were mostly attributed to the silica core, while the polymer coatings had a limited contribution. These findings are important indicators for the future evaluation of the toxicological profile of polymer-coated nanoparticles.     

DNA complexing with polyamidoamine dendrimers: implications for transfection.

DNA and polyamidamine (PAMAM) dendrimers form complexes on the basis of the electrostatic interactions between negatively charged phosphate groups of the nucleic acid and protonated (positively charged) amino groups of the polymers. Charge neutralization of both components and subsequent increases of the net positive charge of the complex result in changes in the physicochemistry and biological properties of the complexes. The formation of soluble, low-density and insoluble, high-density complexes was analyzed using UV light absorption and measurements of radioactive labeled DNA. Formation of high molecular weight and high-density complexes depended mainly on the DNA concentration and was enhanced by increasing the dendrimer-DNA charge ratio. Electrostatic charge related effects (attraction or repulsion of charged particles) appeared to be modulated by the generation of dendrimer (size of the polymer). With the progressive increases in the dendrimer-DNA charge ratio (above 20), an increase in the amount of low-density, soluble complexes was observed. Functional analysis revealed that the great majority (>90%) of transfection is carried by low-density, soluble, complexes which only represent approximately 10-20% of total complexed DNA. The ability of the dendrimer to complex and form aggregates with DNA is crucial for efficient transfection and the function of the complexed DNA.     

Biophysical characterization of quaternary pyridinium functionalized polynorbornenes for DNA complexation and their cellular interactions

Cationic polymers with hydrophobic side chains have gained great interest as DNA carriers since they form a compact complex with negatively charged DNA phosphate groups and interact with the cell membrane. Amphiphilic polyoxanorbornenes with different quaternary alkyl pyridinium side chains with ethyl‐p(OPy2) and hexyl units‐p(OPy6) bearing 10 kDa MWT were synthesized by living Ring‐Opening Metathesis Polymerization method. The physicochemical characteristics: critical micellar concentration, size distribution, surface charge, and condensation of polymer/DNA complex were investigated. Morphology of complexes was monitored by Atomic force microscopy. Cytotoxicity and interaction of these complexes with model lipid vesicles mimicking the cell membrane were examined. These polymers were enabled to form small sized complexes of DNA, which interact with model membrane vesicles. It was found that the nature of hydrophobicity of the homopolymers significantly impacts rates of DNA complexation and the surface charge of the resulting complexes. These results highlight the prospect of the further examinations of these polymers as gene carriers.     

Mechanics of chromatin template activation. Physical evidence for destabilization of nucleoproteins by polyanions.

Thermal denaturation profiles were used to quantitate the destabilizing activity of five classes of polyanions in an effort to explain previously reported differences in activity among apparently similar polymers. This physical assay for polyanion action on chromatin is free of the biochemical complications associated with template assay systems. Most polyanions tested caused a thermal destabilization of the normal nucleohistone complexes of rat thymus chromatin and exposed free or weakly complexed DNA. Polyphosphates dissociated chromatin even when their net charge was as low as 6, and activity per unit of weight increased with chain length only for polymers containing less than about 20 phosphate units; pyrophosphate was inactive. Two polymers which had no influence on chromatin had a low negative charge density. Some, such as polycytidlate and denatured DNA, possessed a high charge but caused only minor changes in the shape of denaturation profiles and exposed little or no free DNA. The highly active nucleic acids, ribosomal RNA and polyguanylate, were distinguishable from inactive nucleic acids by having more secondary structure and potentially less steric hindrance for anionic interaction with chromatin. There was evidence that some polyanions dissociate certain histones before others. Although data obtained show that some histones may be redistributed from chromatin onto added double-stranded DNA in a medium containing urea, this does not appear to interfere significantly with the interpretation of typical thermal denaturation profiles of chromatin.     

DNA packaging induced by micellar aggregates: a novel in vitro DNA condensation system.

Evidence for a conceptually novel DNA packaging process is presented. X-ray scattering, electron microscopy, and circular dichroism measurements indicate that in the presence of positively charged micellar aggregates and flexible anionic polymers, such as negatively charged polypeptides or single-stranded RNA species, a complex is formed in which DNA molecules are partially embedded within a micellar scaffold and partially condensed into highly packed chiral structures. Based on studies of micelle-DNA and micelle-flexible anionic polymer systems, as well as on the known effects of a high charge density upon the micellar organization, a DNA packaging model is proposed. According to this model, the DNA induces the elongation of the micelles into rodlike aggregates, forming a closely packed matrix in which the DNA molecules are immobilized. In contrast, the flexible anionic polymers stabilize clusters of spherical micelles which are proposed to effect a capping of the rodlike micelles, thus arresting their elongation and creating surfactant-free segments of the DNA that are able to converge and collapse. Thus, unlike other in vitro DNA packaging systems, in which condensation follows encounters between charge-neutralized DNA molecules, a prepackaging phase where the DNA is immobilized within a matrix is proposed in this case. Cellular and nuclear membranes have been implicated in DNA packaging processes in vivo, and negatively charged polyelectrolytes were shown to be involved in the processes. These observations, combined with the basic tenets of the DNA condensation system described here, allow for the progression to the study of more elaborate model systems and thus might lead to insights into the nature and roles of the intricate in vivo DNA-membrane complexes.     

Influence of DNA condensation state on transfection efficiency in DNA/polymer complexes: an AFM and DLS comparative study

Atomic force microscopy (AFM) is used to describe the formation process of polymer/DNA complexes. Two main objectives of this research are presented. The first one is to apply AFM as an effective tool to analyse DNA molecules and different polycation/DNA complexes in order to evaluate their degree of condensation (size and shape). The other one is to search for a relationship between the condensation state of DNA and its transfection efficiency. In this study, linear methacrylate based polymers and globular SuperFect polymers are used in order to induce DNA condensation. Ternary complexes, composed of methacrylate based polymers and polyethylene glycol (PEG)-based copolymers, are also investigated. AFM allows us to confirm good condensation conditions and relate them (or not) to transfection efficiencies. These AFM results (obtained after drying in air) are compared with measurements deduced from Dynamic Light Scattering (DLS) experiments performed in water. This comparison allowed us to identify the structural modifications resulting from deposition on the mica surface.     

Endosomal escape of polymeric gene delivery complexes is not always enhanced by polymers buffering at low pH

One of the crucial steps in gene delivery with cationic polymers is the escape of the polymer/DNA complexes ("polyplexes") from the endosome. A possible way to enhance endosomal escape is the use of cationic polymers with a pKa around or slightly below physiological pH ("proton sponge"). We synthesized a new polymer with two tertiary amine groups in each monomeric unit [poly(2-methyl-acrylic acid 2-[(2-(dimethylamino)-ethyl)-methyl-amino]-ethyl ester), abbreviated as pDAMA]. One pKa of the monomer is approximately 9, providing cationic charge at physiological pH, and thus DNA binding properties, the other is approximately 5 and provides endosomal buffering capacity. Using dynamic light scattering and zeta potential measurements, it was shown that pDAMA is able to condense DNA in small particles with a surface charge depending on the polymer/DNA ratio. pDAMA has a substantial lower toxicity than other polymeric transfectants, but in vitro, the transfection activity of the pDAMA-based polyplexes was very low. The addition of a membrane disruptive peptide to pDAMA-based polyplexes considerably increased the transfection efficiency without adversely affecting the cytotoxicity of the system. This indicates that the pDAMA-based polyplexes alone are not able to mediate escape from the endosomes via the proton sponge mechanism. Our observations imply that the proton sponge hypothesis is not generally applicable for polymers with buffering capacity at low pH and gives rise to a reconsideration of this hypothesis.     

Plasmid DNA size does not affect the physicochemical properties of lipoplexes but modulates gene transfer efficiency.

Clinical applications of gene therapy mainly depend on the development of efficient gene transfer vectors. Large DNA molecules can only be transfected into cells by using synthetic vectors such as cationic lipids and polymers. The present investigation was therefore designed to explore the physicochemical properties of cationic lipid-DNA particles, with plasmids ranging from 900 to 52 500 bp. The colloidal stability of the lipoplexes formed by complexing lipopolyamine micelles with plasmid DNA of various lengths, depending on the charge ratio, resulted in the formation of three domains, respectively corresponding to negatively, neutrally and positively charged lipoplexes. Lipoplex morphology and structure were determined by the physicochemical characteristics of the DNA and of the cationic lipid. Thus, the lamellar spacing of the structure was determined by the cationic lipid and its spherical morphology by the DNA. The main result of this study was that the morphological and structural features of the lipopolyamine-DNA complexes did not depend on plasmid DNA length. On the other hand, their gene transfer capacity was affected by the size of plasmid DNA molecules which were sandwiched between the lipid bilayers. The most effective lipopolyamine-DNA complexes for gene transfer were those containing the shortest plasmid DNA.     

Phase diagram, stability, and overcharging of lamellar cationic lipid-DNA self-assembled complexes.

Cationic lipid-DNA (CL-DNA) complexes comprise a promising new class of synthetic nonviral gene delivery systems. When positively charged, they attach to the anionic cell surface and transfer DNA into the cell cytoplasm. We report a comprehensive x-ray diffraction study of the lamellar CL-DNA self-assemblies as a function of lipid composition and lipid/DNA ratio, aimed at elucidating the interactions determining their structure, charge, and thermodynamic stability. The driving force for the formation of charge-neutral complexes is the release of DNA and lipid counterions. Negatively charged complexes have a higher DNA packing density than isoelectric complexes, whereas positively charged ones have a lower packing density. This indicates that the overcharging of the complex away from its isoelectric point is caused by changes of the bulk structure with absorption of excess DNA or cationic lipid. The degree of overcharging is dependent on the membrane charge density, which is controlled by the ratio of neutral to cationic lipid in the bilayers. Importantly, overcharged complexes are observed to move toward their isoelectric charge-neutral point at higher concentration of salt co-ions, with positively overcharged complexes expelling cationic lipid and negatively overcharged complexes expelling DNA. Our observations should apply universally to the formation and structure of self-assemblies between oppositely charged macromolecules.     

Layer-by-layer deposition of oppositely charged polyelectrolytes on the surface of condensed DNA particles.

DNA can be condensed with an excess of poly-cations in aqueous solutions forming stable particles of submicron size with positive surface charge. This charge surplus can be used to deposit alternating layers of polyanions and polycations on the surface surrounding the core of condensed DNA. Using poly-L-lysine (PLL) and succinylated PLL (SPLL) as polycation and polyanion, respectively, we demonstrated layer-by-layer architecture of the particles. Polyanions with a shorter carboxyl/backbone distance tend to disassemble binary DNA/PLL complexes by displacing DNA while polyanions with a longer carboxyl/backbone distance effectively formed a tertiary complex. The zeta potential of such complexes became negative, indicating effective surface recharging. The charge stoichiometry of the DNA/PLL/SPLL complex was found to be close to 1:1:1, resembling poly-electrolyte complexes layered on macrosurfaces. Recharged particles containing condensed plasmid DNA may find applications as non-viral gene delivery vectors.     

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.     

Prevention of biofilm formation by polymer modification

Bacterial biofilm formation on synthetic polymers plays an important role in industry and in modern medicine, leading, for example, to difficult-to-treat infections caused by colonized foreign bodies. Prevention of biofilm formation is a necessary step in the successful prophylaxis of such infections. One approach is to inhibit bacterial adherence by polymer surface modification. We have investigated polymer modification by glow discharge treatment in order to study the influence of the modified surface on bacterial adherence. Surface roughness, surface charge density and contact angles of the modified polymers were determined and related to the adherence ofStaphylococcus epidermidis KH6. Although no influence of surface roughness and charge density on bacterial adherence was noticed, a correlation between the free enthalpy of adhesion (estimated from contact angle measurements) and adherence was observed. There seems to exist a certain minimum bacterial adherence, independent of the nature of the polymer surface. Modified polymers with negative surface charge allow for bacterial adherence close to the adherence minimum. These polymers could be improved further by the ionic bonding of silver ions to the surface. Such antimicrobial polymers are able to prevent bacterial colonization, which is a prerequisite for biofilm formation. It is suggested that modification of polymers and subsequent surface coupling of antimicrobials might be an effective approach for the prevention of bacterial biofilm formation.     

Characterization of DNA/lipid complexes by fluorescence resonance energy transfer

Fluorescence resonance energy transfer (FRET) is a potential method for the characterization of DNA-cationic lipid complexes (lipoplexes). In this work, we used FRET models assuming a multilamellar lipoplex arrangement. The application of these models allows the determination of the distance between the fluorescent intercalator on the DNA and a membrane dye on the lipid, and/or the evaluation of encapsulation efficiencies of this liposomal vehicle. The experiments were carried out in 1,2-dioleoyl-3-trimethylammonium-propane/pUC19 complexes with different charge ratios. We used 2-(3-(diphenylhexatrienyl)propanoyl)-1-hexadecanoyl-sn-glycero-3-phosphocholine (DPH-PC) and 2-(4,4-difluoro-5-octyl-4-bora-3a,4a-diaza-s-indacene-3-pentanoyl)-1-hexadecanoyl-sn-glycero-3-phosphocholine (BODIPY-PC) as membrane dyes, and ethidium bromide (EtBr) and BOBO-1 as DNA intercalators. In cationic complexes (charge ratios (+/-) >or= 2), we verified that BOBO-1 remains bound to DNA, and FRET occurs to the membrane dye. This was also confirmed by anisotropy and lifetime measurements. In complexes with all DNA bound to the lipid (charge ratio (+/-) = 4), we determined 27 A as the distance between the donor and acceptor planes (half the repeat distance for a multilamellar arrangement). In complexes with DNA unbound to the lipids (charge ratio (+/-) = 0.5 and 2), we calculated the encapsulation efficiencies. The presented FRET methodology is, to our knowledge, the first procedure allowing quantification of lipid-DNA contact.     

Development of multicomponent DNA delivery systems based upon poly(amidoamine)-PEG co-polymers

PEGylated polyamidoamine (PAA) polymers were investigated for the production of sterically stabilised DNA delivery systems. Comparison of a PEGylated polymer (NG47) with a non-PEGylated polymer (NG49) showed similar binding of co-polymer to DNA by displacement of ethidium bromide (EB) and DNA melting studies. Gel electrophoresis, turbidimetric analysis and PCS demonstrated differences in the colloidal properties of the complexes, which were attributable to the formation of soluble complexes by the PEGylated co-polymer. However, transmission electron microscopy (TEM) showed that the resulting complexes containing poly(ethylene glycol) (PEG) were not well condensed, susceptible to degradation by nucleases, and thus not suited for in vivo delivery. The poor properties of the PEGylated co-polymer were attributed to an excess of PEG. However, polymer blends of NG47 and NG49 at defined ratios of polymer to co-polymer and total repeating units (RUs) to nucleotide, spontaneously formed complexes with a range of desirable properties. These included small size and polydispersity, high particle density, low surface charge and resistance to nuclease degradation. Complexes made with PEGylated polymer alone, and the polymer blends both suffered from a reduced polyfection activity. This was attributed to a low surface charge on the complex, which reduced interactions with the cell membrane and consequent uptake of the particles into the cell.     

Characterization of a new class of DNA delivery complexes formed by the local anesthetic bupivacaine

Bupivacaine, a local anesthetic and cationic amphiphile, forms stable liposomal-like structures upon direct mixing with plasmid DNA in aqueous solutions. These structures are on the order of 50-70 nm as determined by scanning electron microscopy, and are homogeneous populations as analyzed by density gradient centrifugation. The DNA within these structures is protected from nuclease degradation and UV-induced damage in vitro. Bupivacaine:DNA complexes have a negative zeta potential (surface charge), homogeneous nature, and an ability to rapidly assemble in aqueous solutions. Bupivacaine:DNA complexes, as well as similar complexes of DNA with other local anesthetics, have the potential to be a novel class of DNA delivery agents for gene therapy and DNA vaccines.