Fibrillar oligomers nucleate the oligomerization of monomeric amyloid β but do not seed fibril formation

Abstract

Soluble amyloid oligomers are potent neurotoxins that are involved in a wide range of human degenerative diseases, including Alzheimer disease. In Alzheimer disease, amyloid β (Aβ) oligomers bind to neuronal synapses, inhibit long term potentiation, and induce cell death. Recent evidence indicates that several immunologically distinct structural variants exist as follows: prefibrillar oligomers (PFOs), fibrillar oligomers (FOs), and annular protofibrils. Despite widespread interest, amyloid oligomers are poorly characterized in terms of structural differences and pathological significance. FOs are immunologically related to fibrils because they react with OC, a conformation-dependent, fibril-specific antibody and do not react with antibodies specific for other types of oligomers. However, fibrillar oligomers are much smaller than fibrils. FOs are soluble at 100,000 x g, rich in β-sheet structures, but yet bind weakly to thioflavin T. EPR spectroscopy indicates that FOs display significantly more spin-spin interaction at multiple labeled sites than PFOs and are more structurally similar to fibrils. Atomic force microscopy indicates that FOs are approximately one-half to onethird the height of mature fibrils. We found that Aβ FOs do not seed the formation of thioflavin T-positive fibrils from Aβ monomers but instead seed the formation of FOs from Aβ monomers that are positive for theOCanti-fibril antibody. These results indicate that the lattice of FOs is distinct from the fibril lattice even though the polypeptide chains are organized in an immunologically identical conformation. The FOs resulting from seeded reactions have the same dimensions and morphology as the initial seeds, suggesting that the seeds replicate by growing to a limiting sizeandthensplitting, indicatingthattheirlatticeislessstablethan fibrils. We suggest that FOs may represent small pieces of single fibril protofilament and that the addition of monomers to the ends of FOs is kinetically more favorable than the assembly of the oligomers into fibrils via sheet stacking interaction. These studies provide novel structural insight into the relationship between fibrils and FOs and suggest that the increased toxicity of FOs may be due to their ability to replicate and the exposure of hydrophobic sheet surfaces that are otherwise obscured by sheet-sheet interactions between protofilaments in a fibril. © 2010 by The American Society for Biochemistry and Molecular Biology, Inc.