Among therapeutic approaches for amyloid-related diseases, attention has recently turned to the use of natural products as effective anti-aggregation compounds. Although a wealth of in vitro and in vivo evidence indicates some common inhibitory activity of these compounds, they don’t generally suggest the same mechanism of action. Here, we show that taxifolin, a ubiquitous bioactive constituent of foods and herbs, inhibits formation of HEWL amyloid fibrils and their related toxicity by causing formation of very large globular, chain-like aggregates. A range of amyloid-specific techniques were employed to characterize this process. We found that taxifolin exerts its effect by binding to HEWL prefibrillar species, rather than by stabilizing the molecule in its native-like state. Furthermore, it’s binding results in diverting the amyloid pathway toward formation of very large globular, chain-like aggregates with low β-sheet content and reduced solvent-exposed hydrophobic patches. ThT fluorescence measurements show that the binding capacity of taxifolin is significantly reduced, upon generation of large protofibrillar aggregates at the end of growth phase. We believe these results may help design promising inhibitors of protein aggregation for amyloid-related diseases.
In the present study, we have investigated the effects of protein concentration and stirring on the in vitro assembly of Hen Egg White Lysozyme (HEWL), particularly with regard to the aggregate morphology and anti-amyloidogenic properties of two naturally occurring polyphenols, taxifolin and silibinin. The results obtained clearly demonstrated that applying stirring and concentration enhancement alter the amount as well as morphology of amyloid fibrils formed. Additionally, latter aggregates exhibited higher affinity for amyloid-specific dyes. The second part of the present investigation was devoted to studies involving anti-amyloidogenic properties of selected polyphenols. Importantly, we found that the potency of polyphenols to inhibit HEWL amyloid fibrillation and related toxicity is strongly dependent on the amyloidogenic conditions in which amyloid fibrils are produced. Based on obtained data, under condition where the rate of protein assembly is high (higher protein concentration and stirring), the capacity of polyphenols to inhibit HEWL fibrillogenesis and related cytotoxicity may dramatically decrease. Similar results were obtained when we used taxifolin to inhibit bovine insulin amyloid fibrillation. Additionally, amyloidogenic conditions may also affect the mechanism by which these molecules inhibit HEWL fibrillation. The possible mechanism by which selected polyphenols exert their inhibitory effects, under various experimental conditions, is also discussed.
There are many reports demonstrating that various derivatives of carbon nanoparticles are effective inhibitors of protein aggregation. As surface structural features of nanoparticles play a key role on modulating amyloid fibrillation process, in the present in vitro study, bovine insulin and hen egg white lysozyme (HEWL) were selected as two model proteins to investigate the reducing effect of graphene oxide quantum dots (GOQDs) on their assembly under amyloidogenic conditions. GOQDs were prepared through direct pyrolysis of citric acid, and the reduction step was carried out using ascorbic acid. The prepared nanoparticles were characterized by UV-Vis, X-ray photoelectron, and FT-IR spectroscopies, transmission electron and atomic force microscopies, zeta potential measurement, and Nile red fluorescence assay. They showed the tendencies to modulate the assembly of the proteins through different mechanisms. While GOQDs appeared to have the capacity to inhibit fibrillation, the presence of reduced GOQDs (rGOQDs) was found to promote protein assembly via shortening the nucleation phase, as suggested by ThT fluorescence data. Moreover, the structures produced in the presence of GOQDs or rGOQDs were totally nontoxic. We suggest that surface properties of these particles may be part of the differences in their mechanism(s) of action.
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