Secondary structure and dynamics of micelle bound beta- and gamma-synuclein.

We have used solution state NMR spectroscopy to characterize the secondary structure and backbone dynamics of the proteins beta- and gamma-synuclein in their detergent micelle-bound conformations. Comparison of the results with those previously obtained for the Parkinson's disease-linked protein alpha-synuclein shows that structural differences between the three homologous synuclein family members are directly related to variations in their primary amino acid sequences. An 11-residue deletion in the lipid-binding domain of beta-synuclein leads to the destabilization of an entire segment of the micelle-bound helical structure containing the deletion site. The acidic C-terminal tail region of gamma-synuclein, which displays extensive sequence divergence, is more highly disordered than the corresponding regions in the other two family members. The observed structural differences are likely to mediate functional variations between the three proteins, with differences between alpha- and beta-synuclein expected to revolve around their lipid interactions, while differences in gamma-synuclein function are expected to result from different protein-protein interactions mediated by its unique C-terminal tail.