Expanded polyglutamine (polyQ) sequences cause numerous neurodegenerative diseases which are accompanied by the formation of polyQ fibrils. The unique role of glutamines in the aggregation onset is undoubtedly accepted and...
Polyglutamine (polyQ)
diseases are caused by misfolding and aggregation
of expanded polyQ tracts in the affected protein. PolyQ fibrils have
been studied in detail; however, less is known about oligomeric precursor
states. By a combination of time-resolved temperature-jump (T-jump)
infrared (IR) spectroscopy and an appropriately tailored polyQ model
peptide, we succeeded in disentangling conformational dynamics in
the heterogeneous ensemble of states evolving during aggregation.
Individual structural elements could be differentiated by IR-specific
signatures, i.e., hairpin monomers, β-structured oligomers,
and disordered structure. Submillisecond dynamics were observed for
early oligomeric states in contrast to the slow dynamics of fibril
growth. We propose that a high structural flexibility of oligomers
is required to initiate fibril formation, but not after a fibrillar
structure has consolidated and the fibril just grows. Our study reveals
that structural flexibility changes at different stages in the aggregation
process, from fibril initiation to fibril growth.
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