Characterization of Conformational and Dynamic Properties of Natively Unfolded Human and Mouse α-Synuclein Ensembles by NMR: Implication for Aggregation

Conversion of human α-synuclein (aS) from the free soluble state to the insoluble fibrillar state has been implicated in the etiology of Parkinson's disease. Human aS is highly homologous in amino acid sequence to mouse aS, which contains seven substitutions including the A53T that has been lin...

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Bibliographic Details
Published in:Journal of molecular biology 2008-05, Vol.378 (5), p.1104-1115
Main Authors: Wu, Kuen-Phon, Kim, Seho, Fela, David A., Baum, Jean
Format: Article
Language:English
Subjects:
alpha-Synuclein - chemistry
alpha-Synuclein - metabolism
Amino Acid Sequence
Animals
dynamics
Humans
Mice
Models, Molecular
Molecular Sequence Data
mouse
NMR
Nuclear Magnetic Resonance, Biomolecular
Parkinson Disease - etiology
Parkinson Disease - metabolism
Parkinson Disease - pathology
Parkinson's disease
Protein Folding
Protein Structure, Secondary
Protein Structure, Tertiary
α-synuclein
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Summary:Conversion of human α-synuclein (aS) from the free soluble state to the insoluble fibrillar state has been implicated in the etiology of Parkinson's disease. Human aS is highly homologous in amino acid sequence to mouse aS, which contains seven substitutions including the A53T that has been linked to familial Parkinson's disease, and including five substitutions in the C-terminal region. It has been shown that the rate of fibrillation is highly dependent on the exact sequence of the protein, and mouse aS is reported to aggregate more rapidly than human aS in vitro. Nuclear magnetic resonance experiments of mouse and human aS at supercooled temperatures (263 K) are used to understand the effect of sequence on conformational fluctuations in the disordered ensembles and to relate these to differences in propensities to aggregate. We show that both aS are natively unfolded at low temperature with different propensities to secondary structure, backbone dynamics and long-range contacts across the protein. Mouse aS exhibits a higher propensity to helical conformation around the C-terminal substitutions as well as the loss of transient long-range contacts from the C- to the N-terminal end and hydrophobic central regions of the protein relative to human aS. Lack of back-folding from the C-terminal end of mouse aS exposes the N-terminal region, which is shown, by 15N relaxation experiments, to be very restricted in mobility relative to human aS. We propose that the restricted mobility in the N-terminal region may arise from transient interchain interactions, suggesting that the N-terminal KTK(E/Q)GV repeats may serve as initiation sites for aggregation in mouse aS. These transient interchain interactions coupled with a non-Aβ amyloid component (NAC) region that is both more exposed and has a higher propensity to β structure may accelerate the rate of fibril formation of aS.
ISSN:0022-2836
1089-8638
DOI:10.1016/j.jmb.2008.03.017