RESUMO
Conversion of ß-amyloid (Aß) peptides from soluble random-coil to aggregated protein enriched with ß-sheet-rich intermediates has been suggested to play a role in the degeneration of neurons and development of Alzheimer's disease (AD) pathology. Aggregation of Aß peptide can be prompted by a variety of environmental factors including temperature which can influence disease pathogenesis. Recently, we reported that FDA-approved unconjugated poly (D,L-lactide-co-glycolide) (PLGA) nanoparticles can have beneficial effects in cellular and animal models of AD by targeting different facets of the Aß axis. In this study, using biochemical, structural and spectroscopic analyses, we evaluated the effects of native PLGA on temperature-dependent Aß aggregation and its ability to protect cultured neurons from degeneration. Our results show that the rate of spontaneous Aß1-42 aggregation increases with a rise in temperature from 27 to 40 °C and PLGA with 50:50 resomer potently inhibits Aß aggregation at all temperatures, but the effect is more profound at 27 °C than at 40 °C. It appears that native PLGA, by interacting with the hydrophobic domain of Aß1-42, prevents a conformational shift towards ß-sheet structure, thus precluding the formation of Aß aggregates. Additionally, PLGA triggers disassembly of matured Aß1-42 fibers at a faster rate at 40 °C than at 27 °C. PLGA-treated Aß samples can significantly enhance viability of cortical cultured neurons compared to neurons treated with Aß alone by attenuating phosphorylation of tau protein. Injection of native PLGA is found to influence the breakdown/clearance of Aß peptide in the brain. Collectively, these results suggest that PLGA nanoparticles can inhibit Aß aggregation and trigger disassembly of Aß aggregates at temperatures outside the physiological range and can protect neurons against Aß-mediated toxicity thus validating its unique therapeutic potential in the treatment of AD pathology.