Dendronized Gold Nanoparticles as Carriers for gp160 (HIV-1) Peptides: Biophysical Insight into Complex Formation.

The unavailability of effective and safe human immunodeficiency virus (HIV) vaccines incites several approaches for development of the efficient antigen/adjuvant vaccination composite. In this study, three different dendronized gold nanoparticles (AuNPs 13-15) were investigated for a complexation ability with gp160 synthetic peptides derived from an HIV envelope. It has been shown that HIV peptides interacted with nanoparticles as evident from the changes in their secondary structures, restricted the mobility of the attached fluorescence dye, and enhanced peptide helicity confirmed by the fluorescence polarization and circular dichroism results. Transmission electron microscopy visualized complexes as cloud-like structures with attached nanoparticles. AuNP 13-15 nanoparticles bind negatively charged peptides depending on the number of functional groups; the fastest saturation and peptide retardation were observed for the most dendronized nanoparticle as indicated from dynamic light scattering, laser Doppler velocimetry, and agarose gel electrophoresis experiments. Dendronized gold nanoparticles can be considered one of the potential HIV peptide-based vaccination platforms.

The effect of poly(ethylene glycol) coating and monomer type on poly(alkyl cyanoacrylate) nanoparticle interactions with lipid monolayers and cells.

The interaction of the promising drug carriers poly(alkyl cyanoacrylate) nanoparticles (PACA NPs) with lipid monolayers modeling the cell membrane and with RBE4 immortalized rat brain endothelial cells was compared to assess the relevance of lipid monolayer-based cell membrane models for PACA NP cellular uptake. NP properties such as size and charge of NPs and density of poly(ethylene glycol) coating (PEG) were kept in a narrow range to assess whether the type of PEG coating and the PACA monomer affected NP-monolayer and NP-cell interactions. The interaction with lipid monolayers was evaluated using surface pressure measurements and Brewster angle microscopy. NP association with and uptake by cells were assessed using flow cytometry and confocal laser scanning microscopy. The interaction between NPs and both lipid monolayers and the plasma membrane depended on the type of PEG. PEG density affected cellular uptake but not interaction with lipid monolayers. NP monomer, NPs size and charge had no effect on the interaction. This might be due to the fact that the size and charge distribution was kept rather narrow to study the effect of PACA monomer and PEG type. In conclusion, while modeling solely the passive aspect of NP-cell interactions, lipid monolayers nevertheless proved a valuable cell membrane model whose interaction with PACA NPs correlated well with NP-cell interaction. In addition, both NP-monolayer and NP-cell interactions were dependent on PEGylation type, which could be used in the design of NPs to either facilitate or hinder cellular uptake, depending on the intended purpose.