Water-soluble biodegradable cationic polyphosphazenes for gene delivery.

Polyphosphazenes bearing cationic moieties were synthesized from poly(dichloro)phosphazene, which in turn was obtained by thermal polymerization of hexachlorocyclotriphosphazene in 1,2,4-trichlorobenzene. Next, either 2-dimethylaminoethanol (DMAE) or 2-dimethylaminoethylamine (DMAEA) side groups were introduced by a substitution reaction. The polymers were purified by dialysis against water and tetrahydrofuran, lyophilized and evaluated as polymeric transfectants. The polyphosphazenes were able to bind plasmid DNA yielding positively charged particles (polyplexes) with a size around 80 nm at a polymer/DNA ratio of 3:1 (w/w). The polyphosphazene-based polyplexes were able to transfect COS-7 cells in vitro with an efficiency comparable to a well-known polymeric transfectant [poly(2-dimethylaminoethyl methacrylate), pDMAEMA]. The toxicity of both polyphosphazenes was lower than pDMAEMA. The transfection efficiency for the poly(DMAE)phosphazene-based polyplexes was about threefold higher in the absence of serum than in the presence of 5.0% fetal bovine serum. This is probably caused by unfavorable interactions of the polyplexes with serum proteins. In contrast, the poly(DMAEA)phosphazene-based polyplexes showed a threefold lower transfection activity in the absence of serum. For this system, serum proteins likely masked the toxicity of the polyplexes, as shown by the XTT cell viability assay and confocal laser scanning microscopy studies. Preliminary degradation studies indicate that the polymers were indeed degradable. The half-life at pH 7.5 and 37 degrees C was around 7 days for poly(DMAE)phosphazenes and 24 days for poly(DMAEA)phosphazenes. This study shows that polyphosphazenes are a suitable and promising new class of biodegradable polymeric carriers for gene delivery.

Copolymers of 2-(dimethylamino)ethyl methacrylate with ethoxytriethylene glycol methacrylate or N-vinyl-pyrrolidone as gene transfer agents.

Random copolymers of 2-(dimethylamino)ethyl methacrylate (DMAEMA) with ethoxytriethylene glycol methacrylate (triEGMA) or N-vinylpyrrolidone (NVP) of different molecular weights and compositions were synthesized, characterized and evaluated as polymeric transfectants in vitro. All synthesized copolymers (comonomer fraction up to 66 mol%) were able to bind to DNA, yielding polymer-plasmid complexes (polyplexes). However, the polymer-plasmid ratio at which small complexes (size 0.2-0.3 microm) were formed, increased with increasing mole fraction of the comonomer. zeta-Potential measurements revealed that the polymer-plasmid ratio where charge neutralization of DNA occurred, increased with increasing mole fraction of triEGMA. The cytotoxicity of the copolymers, either complexed with DNA or in the free form, decreased with increasing mole fraction of both comonomers (triEGMA and NVP). This reduction was even more than what could be expected based on the DMAEMA mole fraction in the copolymer. The copolymers with a molecular weight up to 170¿ omitted¿000 had the same transfection capability as a homopolymer of comparable molecular weight. However, higher molecular weight copolymers showed a reduced transfection capability compared to the homopolymer, which was ascribed to the reduced capability to condense the size of plasmid. Transfection efficiency of polyplexes composed of copolymers with a low triEGMA content increased with increasing molecular weight. Although the copolymers with 50 mol% triEGMA were also better transfectants than the homopolymer, the transfection efficiency did not increase further with increasing molecular weight. Interestingly, NVP-DMAEMA copolymers synthesized by polymerization to high conversion showed both excellent DNA binding and condensing characteristics (polyplex size <0.3 microm) and transfection capabilities. This is ascribed to a synergistic effect of DMAEMA-rich copolymers and NVP-rich copolymers present in this system on the complex formation with plasmid DNA.

Structure-activity relationships of water-soluble cationic methacrylate/methacrylamide polymers for nonviral gene delivery.

A number of water-soluble cationic carriers was evaluated as transfectant. Almost all studied cationic methacrylate/methacrylamide polymers were able to condense the structure of plasmid DNA, yielding polymer/plasmid complexes (polyplexes) with a size of 0.1-0.3 micron and a slightly positive zeta-potential, which can be taken up by cells, e.g., via endocytosis. However, the transfection efficiency and the cytotoxicity of the polymers differed widely: the highest transfection efficiency and cytotoxicity were observed for poly[2-(dimethylamino)ethyl methacrylate], p(DMAEMA). Assuming that polyplexes enter cells via endocytosis, p(DMAEMA) apparently has advantageous properties to escape the endosome. A possible explanation is that, due to its average pK(a) value of 7.5, p(DMAEMA) is partially protonated at physiological pH and might behave as a proton sponge. This might cause a disruption of the endosome, which results in the release of both the polyplexes and cytotoxic endosomal/lysosomal enzymes into the cytosol. On the other hand, the analogues of p(DMAEMA) studied here have a higher average pKa value and have, consequently, a higher degree of protonation and a lower buffering capacity. This might be associated with a lower tendency to destabilize the endosome, resulting in both a lower transfection efficiency and a lower cytotoxicity. Furthermore, molecular modeling showed that, of all studied polymers, p(DMAEMA) has the lowest number of interactions with DNA. We therefore hypothesized that the superior transfection efficiency of p(DMAEMA) containing polyplexes can be ascribed to an intrinsic property of p(DMAEMA) to destabilize endosomes combined with an easy dissociation of the polyplex once present in the cytosol and/or the nucleus.

Thermosensitive polymers as carriers for DNA delivery.

Copolymers of 2-(dimethylamino) ethyl methacrylate (DMAEMA) and N-isopropylacryl amide (NIPAAm) of various monomer ratios and molecular weights were evaluated as carrier systems for DNA delivery. All copolymers, even with a low DMAEMA content of 15 mol%, were able to bind to DNA at 25 degrees C. Light-scattering measurements indicate that complexation is accompanied by precipitation of the (co)polymer in the complex caused by a drop of the lower critical solution temperature of the (co)polymer. The (co)polymer/plasmid ratio at which complexes with a size of around 200 nm were formed increased with increasing NIPAAm content of the copolymer and was independent of molecular weight of the (co)polymer. However, complexes containing (co)polymers of low molecular weight or high NIPAAm content prepared at 25 degrees C aggregated rapidly when the temperature was raised to 37 degrees C, whereas complexes containing (co)polymers of high molecular weight or lower NIPAAm content were relatively stable at 37 degrees C. The zeta potential of the complexes was also independent of molecular weight of the (co)polymer and increased with increasing (co)polymer/plasmid ratio until a plateau value was reached. The (co)polymer/plasmid ratio at which this plateau was reached increased with increasing NIPAAm content. The plateau values decreased from around 26 mV to around 13 mV when the NIPAAm content of the copolymer was increased from 0 to 85 mol%. The cytotoxicity of the complexes strongly decreased with increasing NIPAAm content and was independent of molecular weight of the (co)polymer. The transfection efficiency of complexes with poor stability was in general much lower than that of complexes with good stability. The transfection efficiency as a function of the (co)polymer/plasmid ratio showed a bell-shaped curve. The (co)polymer/plasmid ratio at which the transfection efficiency was maximal increased with increasing NIPAAm content, while the maximum transfection efficiency strongly decreased with increasing NIPAAm content of the copolymer. The results of this study show that the formation of stable (co)polymer/plasmid complexes with a size of around 200 nm is a prerequisite for efficient transfection. Furthermore, the transfection efficiency and cytotoxicity strongly decreased with decreasing zeta potential. Therefore, besides the size, the zeta potential can also be used as a characteristic to predict the behavior of this type of (co)polymer/plasmid complexes in transfection. Copolymers of DMAEMA and NIPAAm provided with a homing device may be interesting carrier systems for gene targeting because these copolymers can condense DNA to small particles, and the resulting complexes show a low cytotoxicity and aspecific transfection.

Effect of DNA topology on the transfection efficiency of poly((2-dimethylamino)ethyl methacrylate)-plasmid complexes.

In this paper the effect of the topology of plasmid DNA (supercoiled, open-circular and linear) on its binding characteristics with the polymeric transfectant poly((2-dimethylamino)ethyl methacrylate) was studied. The formed polyplexes were also evaluated for their transfection properties in vitro in two different cell lines. Anion-exchange chromatography was used for the separation of supercoiled and open-circular plasmid from a plasmid stock solution. Linear plasmids were prepared by endonucleases that cleaved the plasmid either in the promoter region or in a region not specific for expression (ampicillin resistance region). Plasmid DNA was also heat-denatured for 6 h at 70 degrees C, resulting in DNA mainly in the open-circular and oligomeric forms. The transfection of two different cell lines was dependent on the topology of the DNA in the order supercoiled>open-circular approximately heat-denatured>linear DNA prepared by cleaving in the nonspecific region>linear DNA prepared by cleaving in the promoter region. No differences in the size of the complexes or in the quenching of the DNA-intercalating fluorophore acridine orange were found as function of the topology. However, circular dichroism spectroscopy revealed differences between the topological plasmid species, both in the free form and in the presence of excess of cationic polymer.

Comparative transfection studies of human ovarian carcinoma cells in vitro, ex vivo and in vivo with poly(2-(dimethylamino)ethyl methacrylate)-based polyplexes.

BACKGROUND: Poly(2-(dimethylamino)ethyl methacrylate) (p(DMAEMA)) can be used successfully for in vitro transfection of different cell lines, including the OVCAR-3 human ovarian carcinoma cell line. The aim of this study was to investigate whether it is possible to transfect OVCAR-3 cells in vivo with polyplexes containing p(DMAEMA). METHODS: In order to understand the generally observed gap between in vitro and in vivo transfection, we gradually went from in vitro to in vivo transfection of OVCAR-3 cells, while keeping the exposure conditions the same, as far as possible. To find the reason for the negligible degree of in vivo transfection, in vitro cultured OVCAR-3 cells were transfected in the presence of peritoneal ascites fluid. Next, the influence of hyaluronic acid, one of the ascites components, on the transfection efficiency was studied. RESULTS: P(DMAEMA)-containing polyplexes can transfect OVCAR-3 cells in vitro with an overall transfection efficiency of 10%. Cells grown in vivo can be transfected ex vivo with p(DMAEMA)/plasmid complexes with an overall transfection efficiency of approximately 1-2%. When transfection complexes are injected i.p. into nude mice bearing OVCAR-3 cells in the peritoneal cavity, the degree of in vivo transfection efficiency achieved is negligible. In vitro cultured OVCAR-3 cells were also transfected with polyplexes in the presence of peritoneal ascites fluid. The results indicate that one or more components of ascites had a negative effect on the transfection efficiency of p(DMAEMA)-containing polyplexes. To elucidate which component(s) of ascites may have interfered, the influence of hyaluronic acid, one of the ascites components, on the transfection efficiency was studied. The outcome suggests that hyaluronic acid may have induced a negative effect on the transfection capability of p(DMAEMA)-containing polyplexes. CONCLUSION: P(DMAEMA) is an efficient transfectant in vitro and ex vivo. However, transfected cells were not detected in vivo which may be caused by a negative influence of components of the ascites fluid.