The effect of pH on PAMAM dendrimer-siRNA complexation:endosomal considerations as determined by molecular dynamics simulation

Intracellular degradation of genes, most notably within the endo-lysosomal compartment is considered a significant barrier to (non-viral) gene delivery in vivo. Previous reports based on in vitro studies claim that carriers possessing a mixture of primary, secondary and tertiary amines are able to buffer the acidic environment within the endosome, allowing for timely release of their contents, leading to higher transfection rates. In this report, we adopt an atomistic molecular dynamics (MD) simulation approach, comparing the complexation of 21-bp siRNA with low-generation polyamidoamine (PAMAM) dendrimers (G0 and G1) at both neutral and acidic pHs, the latter of which mimics the degradative environment within maturing 'late-endosomes'. Our simulations reveal that the time taken for the dendrimer-gene complex (dendriplex) to reach equilibrium is appreciably longer at low pH and this is accompanied by more compact packaging of the dendriplex, as compared to simulations performed at neutral pH. We also note larger absolute values of calculated binding free energies of the dendriplex at low pH, indicating a higher dendrimer-nucleic acid affinity in comparison with neutral pH. These novel simulations provide a more detailed understanding of low molecular-weight polymer-siRNA behavior, mimicking the endosomal environment and provide input of direct relevance to the "proton sponge theory", thereby advancing the rational design of non-viral gene delivery systems.

Evaluation of biodegradable polymer microspheres and an anionic dendrimer for the potential delivery of antisense oligonucleotides

Antisense oligonucleotides (AODNs) can selectively inhibit individual gene expression by binding specifically to rnRNA. The over-expression of the epidermal growth factor receptor (EGFR) has been observed in human breast and glioblastoma tumours and therefore AODNs designed to target the EGFR would be a logical approach to treat such tumours. However, poor pharmacokinetic/pharmacodynamic and cellular uptake properties of AODNs have limited their potential to become successful therapeutic agents. Biodegradable polymeric poly (lactide-co-glycolide) (P(LA-GA)) and dendrimer delivery systems may allow us to overcome these problems. The use of combination therapy of AODNs and cytotoxic agents such as 5-fluorouracil (5-FU) in biodegradable polymeric formulations may further improve therapeutic efficacy. AODN and 5-FU were either co-entrapped in a single microsphere formulation or individually entrapped in two separate microsphere formulations (double emulsion method) and release profiles determined in vitro. The release rates (biphasic) of the two agents were significantly slower when co-entrapped as a single microsphere formulation compared to those obtained with the separate formulations. Sustained release over 35 days was observed in both types of formulation. Naked and microsphere-loaded AODN and 5-FU (in separate formulations) were tested on an A431 vulval carcinoma cell line. Combining naked or encapsulated drugs produced a greater reduction in viable cell number as compared with either agent alone. However, controls and Western blotting indicated that non-sequence specific cytotoxic effects were responsible for the differences in viable cell number. The uptake properties of an anionic dendrimer based on a pentaerythritol structure covalently linked to AODNs (targeting the EGFR) have been characterised. The cellular uptake of AODN linked to the dendrimer was up to 3.5-fold higher in A431 cells as compared to naked AODN. Mechanistic studies suggested that receptor-mediated and adsorptive (binding protein-mediated) endocytosis were the predominant uptake mechanisms for the dendrimer-AODN. RNase H cleavage assay suggested that the dendrimer-AODN was able to bind and cleave the target site. A reduction of 20%, 28% and 45% in EGFR expression was observed with 0.05μM, 0.1μM and 0.5μM dendrimer-AODN treatments respectively with a reduction in viable cell number. These results indicated that the dendrimer delivery system may reduce viable cell number by an antisense specific mechanism.