Polyplexes assembled from poly(aspartamide) derivatives bearing 1,2-diaminoethane side chains, [PAsp(DET)] display amplified in vitro and in vivo transfection activity with minimal cytotoxicity. To elucidate the molecular mechanisms involved in this unique function of PAsp(DET) polyplexes, the physicochemical and biological properties of PAsp(DET) were thoroughly evaluated with a control bearing 1,3-diaminopropane side chains, PAsp(DPT). Between PAsp(DET) and PAsp(DPT) polyplexes, we observed negligible physicochemical differences in particle size and zeta-potential. However, the one methylene variation between 1,2-diaminoethane and 1,3-diaminopropane drastically altered the transfection profiles. In sharp contrast to the constantly high transfection efficacy of PAsp(DET) polyplexes, even in regions of excess polycation to plasmid DNA (pDNA) (high N/P ratio), PAsp(DPT) polyplexes showed a significant drop in the transfection efficacy at high N/P ratios due to the progressively increased cytotoxicity with N/P ratio. The high cytotoxicity of PAsp(DPT) was closely correlated to its strong destabilization effect on cellular membrane estimated by hemolysis, leakage assay of cytoplasmic enzyme (LDH assay), and confocal laser scanning microscopic observation. Interestingly, PAsp(DET) revealed minimal membrane destabilization at physiological pH, yet there was significant enhancement in the membrane destabilization at the acidic pH mimicking the late endosomal compartment (pH approximately 5). Apparently, the pH-selective membrane destabilization profile of PAsp(DET) corresponded to a protonation change in the flanking diamine unit, i.e., the monoprotonated gauche form at physiological pH and diprotonated anti form at acidic pH. These significant results suggest that the protonated charge state of 1,2-diaminoethane may play a substantial role in the endosomal disruption. Moreover, this novel approach for endosomal disruption neither perturbs the membranes of cytoplasmic vesicles nor organelles at physiological pH. Thus, PAsp(DET) polyplexes, residing in late endosomal or lysosomal states, smoothly exit into the cytoplasm for successful transfection without compromising cell viability.
The CPT/m released the drug responding to reductive conditions. The PCI-induced endosomal escape exposed CPT/m to the cytosol triggering the drug release. Thus, CPT/m in combination with DPc/m will behave as smart nanocarriers activated only at photoirradiated tissues.
Purpose
Polyelectrolyte complex nanoparticles are a promis ing vehicle for siRNA delivery but suffer from low stability under physiological conditions. An effective stabilization meth od is essential for the success of polycationic nanoparticle mediated siRNA delivery. In this study, sodium triphosphate (TPP), an ionic crosslinking agent, is used to stabilize siRNA containing nanoparticles by co condensation.
Methods
siRNA and TPP were co encapsulated into a block copolymer, poly(ethylene glycol) b polyphosphoramidate (PEG b PPA), to form ternary nanoparticles. Physicochemical characterization was performed by dynamic light scattering and gel electrophoresis. Gene silencing efficiency in cell lines was assessed by dual luciferase assay system.
Results
The PEG b PPA/siRNA/TPP ternary nanoparticles exhibited high uniformity with smaller size (80 100 nm) compared with PEG b PPA/siRNA nanoparticles and showed increased stability in physiological ionic strength and serum containing medium, due to the stabilization effect from ionic crosslinks between negatively charged TPP and cationic PPA segment. Transfection and gene silencing efficiency of the TPP crosslinked nanoparticles were markedly improved over PEG b PPA/siRNA complexes in serum containing medium. No significant difference in cell viability was observed between nanoparticles prepared with and without TPP co condensation.
Conclusions
These results demonstrated the effectiveness of TPP co condensation in compacting polycation/siRNA nano particles, improving nanoparticle stability and enhancing the transfection and knockdown efficiency in serum containing medium.
PurposeThe choriocapillaris (CC), the capillary network of the choroid, is positioned adjacent to Bruch's membrane (BM) and the RPE. The aim of this study was to clarify the mechanism(s) for transport of serum albumen from CC lumen to RPE.MethodsAlexa647 conjugated to BSA (BSA-A647) or PBS was administrated via the femoral vein to young and aged wild-type (WT; C57BL/6J) mice and Caveolin-1 knockout mice (Cav1−/−). Mice were perfused with PBS and killed at 30 minutes, 1 hour, and 4 hours after injection. Eyecups were cryopreserved, and cryosections were analyzed on a Zeiss 710 confocal microscope. Bovine serum albumin conjugated to gold nanoparticles (BSA-GNP) was administrated through the left common carotid artery. Mice were perfused with PBS and killed at 30 minutes after injection. Eyecups were embedded after fixation, and 70-nm-thick sections were analyzed on a Hitachi H7600 transmission electron microscope.ResultsIn eyes of WT young mice, BSA-A647 was transported to the RPE at 30 minutes and diffused to the photoreceptor layer by 1 hour. In contrast, most BSA-A647 was found in the CC in Cav1−/− eyes. The majority of BSA-GNP found in the CC of young WT mice was on the luminal side in caveolae at 30 minutes after injection. In aged WT mice, BSA-GNPs were found in defective tight junctions between endothelial cells and appeared trapped at the diaphragm of fenestrations.ConclusionsNormally, CC carefully regulates transport system of BSA from lumen to BM by caveolae-mediated transcytosis; however, endothelium cells of aged control WT mice have leaky tight junctions and lacked regulated BSA transport.
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