One or more β-amyloid(s)? New insights into the prion-like nature of Alzheimer's disease

Degradation and/or Dissociation of Neurodegenerative Disease-Related Factor Amyloid-β by a Suspension Containing Calcium Hydrogen Carbonate Mesoscopic Crystals

Amyloid-β (Aβ) aggregates accumulate in the brains of individuals with Alzheimer's disease and are thought to potentially act as prions, promoting further aggregation. Consequently, the biochemistry of Aβ has emerged as a promising target for Alzheimer's disease. CAC-717, a suspension of calcium bicarbonate mesoscopic structures derived from natural sources, has been shown to inactivate various pathogens, including prions. This study examined the effects of CAC-717 on both the formation and degradation/dissociation of Aβ aggregates using thioflavin T fluorescence and enzyme-linked immunosorbent assays. Aggregates of Aβ(1-42) peptide were generated by incubation at 37 °C for 24 h, and the effect of introducing CAC-717 on the aggregates was evaluated after further incubation at 25 °C for 30 min. Moreover, CAC-717 was also tested for its ability to inhibit the initial aggregation of Aβ. The results showed that CAC-717 significantly degraded and/or dissociated Aβ aggregates in a concentration-dependent manner. Specifically, CAC-717 treatment for 5 min disrupted Aβ aggregates to give Aβ monomer and oligomer concentrations as high as 130 nM compared to ~10 nM for the water control. In addition, CAC-717 degraded and/or dissociated aggregates within 10 s at 37 °C, and pre-treatment with CAC-717 significantly inhibited aggregation. These results suggest that CAC-717 not only degrades and/or dissociates Aβ aggregates but also inhibits their formation, highlighting its potential as a disinfectant for Alzheimer's disease.

Amyloid-type Protein Aggregation and Prion-like Properties of Amyloids

This review will focus on the process of amyloid-type protein aggregation. Amyloid fibrils are an important hallmark of protein misfolding diseases and therefore have been investigated for decades. Only recently, however, atomic or near-atomic resolution structures have been elucidated from various in vitro and ex vivo obtained fibrils. In parallel, the process of fibril formation has been studied in vitro under highly artificial but comparatively reproducible conditions. The review starts with a summary of what is known and speculated from artificial in vitro amyloid-type protein aggregation experiments. A partially hypothetic fibril selection model will be described that may be suitable to explain why amyloid fibrils look the way they do, in particular, why at least all so far reported high resolution cryo-electron microscopy obtained fibril structures are in register, parallel, cross-β-sheet fibrils that mostly consist of two protofilaments twisted around each other. An intrinsic feature of the model is the prion-like nature of all amyloid assemblies. Transferring the model from the in vitro point of view to the in vivo situation is not straightforward, highly hypothetic, and leaves many open questions that need to be addressed in the future.