Intrinsic Structural Heterogeneity and Long-Term Maturation
of Amyloid β Peptide Fibrils
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Abstract
Amyloid β peptides
form fibrils that are commonly assumed to have a dry, homogeneous,
and static internal structure. To examine these assumptions, fibrils
under various conditions and different ages have been examined with
multidimensional infrared spectroscopy. Each peptide in the fibril
had a <sup>13</sup>C<sup>18</sup>O label in the backbone of
one residue to disinguish the amide I′ absorption due to that
residue from the amide I′ absorption of other residues. Fibrils
examined soon after they formed, and reexamined after 1 year in the
dry state, exhibited spectral changes confirming that structurally
significant water molecules were present in the freshly formed fibrils.
Results from fibrils incubated in solution for 4 years indicate that
water molecules remained trapped within fibrils and mobile over the
4 year time span. These water molecules are structurally significant
because they perturb the parallel β-sheet hydrogen bonding pattern
at frequent intervals and at multiple points within individual fibrils,
creating structural heterogeneity along the length of a fibril. These
results show that the interface between β-sheets in an amyloid
fibril is not a “dry zipper”, and that the internal
structure of a fibril evolves while it remains in a fibrillar state.
These features, water trapping, structural heterogeneity, and structural
evolution within a fibril over time, must be accommodated in models
of amyloid fibril structure and formation