AI Article Synopsis
- The study simulates the formation of ordered amyloid-like beta structures using 18 polyvaline chains in a solvent, employing molecular dynamics and bias-exchange metadynamics to explore different structures.
- The researchers analyzed hundreds of possible configurations focusing on varying parallel and antiparallel β-sheets to understand the free energy landscapes and the nucleation process.
- The findings indicate that amyloid fibril formation begins with the creation of an antiparallel β-sheet nucleus, later followed by the emergence of parallel sheets, illustrating a complex nucleation pathway that can't be simplified to a single reaction coordinate as per classical nucleation theory.
Article Abstract
Starting from a disordered aggregate, we have simulated the formation of ordered amyloid-like beta structures in a system formed by 18 polyvaline chains in explicit solvent, employing molecular dynamics accelerated by bias-exchange metadynamics. We exploited 8 different collective variables to compute the free energy of hundreds of putative aggregate structures, with variable content of parallel and antiparallel β-sheets and different packing among the sheets. This allowed characterizing in detail a possible nucleation pathway for the formation of amyloid fibrils: first the system forms a relatively large ordered nucleus of antiparallel β-sheets, and then a few parallel sheets start appearing. The relevant nucleation process culminates at this point: when a sufficient number of parallel sheets is formed, the free energy starts to decrease toward a new minimum in which this structure is predominant. The complex nucleation pathway we found cannot be described within classical nucleation theory, namely employing a unique simple reaction coordinate like the total content of β-sheets.
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| http://dx.doi.org/10.1021/ja210826a | DOI Listing |
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