Abstract
At the core of amyloid fibrils is the cross-β spine, a long tape of β-sheets formed by the constituent proteins. Recent high-resolution x-ray studies show that the unit of this filamentous structure is a β-sheet bilayer with side chains within the bilayer forming a tightly interdigitating “steric zipper” interface. However, for a given peptide, different bilayer patterns are possible, and no quantitative explanation exists regarding which pattern is selected or under what condition there can be more than one pattern observed, exhibiting molecular polymorphism. We address the structural selection mechanism by performing molecular dynamics simulations to calculate the free energy of incorporating a peptide monomer into a β-sheet bilayer. We test filaments formed by several types of peptides including GNNQQNY, NNQQ, VEALYL, KLVFFAE and STVIIE, and find that the patterns with the lowest binding free energy correspond to available atomistic structures with high accuracy. Molecular polymorphism, as exhibited by NNQQ, is likely because there are more than one most stable structures whose binding free energies differ by less than the thermal energy. Detailed analysis of individual energy terms reveals that these short peptides are not strained nor do they lose much conformational entropy upon incorporating into a β-sheet bilayer. The selection of a bilayer pattern is determined mainly by the van der Waals and hydrophobic forces as a quantitative measure of shape complementarity among side chains between the β-sheets. The requirement for self-complementary steric zipper formation supports that amyloid fibrils form more easily among similar or same sequences, and it also makes parallel β-sheets generally preferred over anti-parallel ones. But the presence of charged side chains appears to kinetically drive anti-parallel β-sheets to form at early stages of assembly, after which the bilayer formation is likely driven by energetics.
Highlights
Amyloid fibrils are hallmarks of several neurodegenerative diseases including Alzheimer’s, Parkinson’s, and prion diseases [1]
Unlike other protein quaternary structures [2], amyloid fibrils share a sequence independent structural motif known as the crossb spine; individual strands from constituent proteins forming a bsheet that runs perpendicular to the fibril axis [3]
Our present analysis implies subtle roles played by kinetics and energetics in amyloid assembly
Summary
Amyloid fibrils are hallmarks of several neurodegenerative diseases including Alzheimer’s, Parkinson’s, and prion diseases [1]. Amyloid fibrillogenesis is a multi-staged protein aggregation process and accumulating evidence suggests that prefibrillar oligomeric species are toxic [4]. Amyloid protofibrils as well as oligomers have been suggested to lead to neuronal cell death [5,6,7,8]. Interruption of fibril formation prevented cell damage [9], and b-sheet rich diffusible oligomeric species of A b, the chief constituent of amyloid fibrils in Alzheimer’s disease, possess cytotoxicity, which share structural similarity to mature fibrils [10]. Recent findings suggest even greater biological role of amyloid fibrils: amyloid fibrils in semen accelerated HIV infection [12]; a functional, mammalian amyloid composed of a protein Pmel promoted the formation of melanin [13]. De novo designed peptides self-assemble into amyloid-like b-sheet filaments, and hydrogels composed of these filaments hold a great potential for three-dimensional cell culture scaffold [14,15]
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