The use of antisense oligodeoxynucleotides (ODNs) to inhibit the expression of specific mRNA targets represents a powerful technology for control of gene expression. Cationic lipids and polymers are frequently used to improve the delivery of ODNs to cells, but the resulting complexes often aggregate, bind to serum components, and are trafficked poorly within cells. We show that the addition of a synthetic, pH-sensitive, membrane-disrupting polyanion, poly(propylacrylic acid) (PPAA), improves the in vitro efficiency of the cationic lipid, DOTAP, with regard to oligonucleotide delivery and antisense activity. In characterization studies, ODN complexation with DOTAP/ODN was maintained even when substantial amounts of PPAA were added. The formulation also exhibited partial protection of phosphodiester oligonucleotides against enzymatic digestion. In Chinese hamster ovary (CHO) cells, incorporation of PPAA in DOTAP/ODN complexes improved two-to threefold the cellular uptake of fluorescently tagged oligonucleotides. DOTAP/ODN complexes containing PPAA also maintained high levels of uptake into cells upon exposure to serum. Addition of PPAA to DOTAP/ODN complexes enhanced the antisense activity (using GFP as the target) over a range of PPAA concentrations in both serum-free, and to a lesser extent, serum-containing media. Thus, PPAA is a useful adjunct that improves the lipid-mediated delivery of oligonucleotides.
The widespread utilization of gene silencing techniques, such as antisense, is impeded by the poor cellular delivery of oligonucleotides (ONs). Rational design of carriers for enhanced ON delivery demands a better understanding of the role of the vector on the extent and time course of antisense effects. The aim of this study is to understand the effects of polymer molecular weight (MW) and ON backbone chemistry on antisense activity. Complexes were prepared between branched polyethyleneimine (PEI) of various MWs and ONs of phosphodiester and phosphorothioate chemistries. We measured their physico-chemical properties and evaluated their ability to deliver ONs to cells, leading to an antisense response. Our key finding is that the antisense activity is not determined solely by PEI MW or by ON chemistry, but rather by the interplay of both factors. While the extent of target mRNA down-regulation was determined primarily by the polymer MW, dynamics were determined principally by the ON chemistry. Of particular importance is the strength of interactions between the carrier and the ON, which determines the rate at which the ONs are delivered intracellularly. We also present a mathematical model of the antisense process to highlight the importance of ON delivery to antisense down-regulation.
We aim to compare quantitatively the dynamics of the effectiveness of antisense oligonucleotides (AS ODNs) versus short interfering RNAs (siRNAs) and relate their effectiveness to sequence metrics (e.g., predicted free energy of binding). AS ODNs against a quantitative model target, pd1EGFP (destabilized enhanced GFP [green fluorescent protein]), were selected using our thermodynamic model, and siRNA sequences were designed to be identical to the AS ODN sequences in the antisense strand. We evaluated d1EGFP inhibition in transiently and stably transfected Chinese hamster ovary (CHO) cells over time using flow cytometry. Overall, our results show that the rationally designed AS ODN and siRNA sequences proved effective inhibitors of GFP expression and suggest that certain regions of mRNA may be susceptible to both AS ODNs and siRNAs.
We used static light scattering to obtain new measurements on the internal structure of aggregated non-viral gene-delivery particles in colloidal suspension. The vector particles are prepared by charge neutralization of plasmid DNA either by poly-L-lysine or by a Lipofectin/integrin-targeting peptide. We use established theories of the stability of colloidal particles and fractal concepts to explain the aggregation processes and demonstrate the existence of a new property (fractal dimension) of the aggregated vector particles. Aggregation is shown to produce particles with fractal dimensions in the range between 1.8 and 2.4; the former suggests a loose three-dimensional structure and the latter characterizes an aggregation process that leads to the formation of particles with tightly packed structures. We show that the fractal dimension of the vector particles is sensitive to changes in physicochemical conditions (ionic strength) of the buffer solution and propose that fractal dimension may provide a useful means of monitoring the physical state of non-viral delivery-vector particles during preparation and storage.
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