Abstract
The intrinsically disordered human protein α-synuclein (αSN) can self-associate into oligomers and amyloid fibrils. Several lines of evidence suggest that oligomeric αSN is cytotoxic, making it important to devise strategies to either prevent oligomer formation and/or inhibit the ensuing toxicity. (−)-epigallocatechin gallate (EGCG) has emerged as a molecular modulator of αSN self-assembly, as it reduces the flexibility of the C-terminal region of αSN in the oligomer and inhibits the oligomer's ability to perturb phospholipid membranes and induce cell death. However, a detailed structural and kinetic characterization of this interaction is still lacking. Here, we use liquid-state NMR spectroscopy to investigate how EGCG interacts with monomeric and oligomeric forms of αSN. We find that EGCG can bind to all parts of monomeric αSN but exhibits highest affinity for the N-terminal region. Monomeric αSN binds ∼54 molecules of EGCG in total during oligomerization. Furthermore, kinetic data suggest that EGCG dimerization is coupled with the αSN association reaction. In contrast, preformed oligomers only bind ∼7 EGCG molecules per protomer, in agreement with the more compact nature of the oligomer compared with the natively unfolded monomer. In previously conducted cell assays, as little as 0.36 EGCG per αSN reduce oligomer toxicity by 50%. Our study thus demonstrates that αSN cytotoxicity can be inhibited by small molecules at concentrations at least an order of magnitude below full binding capacity. We speculate this is due to cooperative binding of protein-stabilized EGCG dimers, which in turn implies synergy between protein association and EGCG dimerization.
Highlights
Determination of the stoichiometry of epigallocatechin gallate (EGCG) binding to αSN monomer by conventional titration is complicated by the fact that αSN oligomerizes in a time-dependent manner when EGCG is present [8, 16]
EGCG drives αSN into oligomers of defined stoichiometry in a concerted manner The small flavonoid polyphenol EGCG is able to promote the formation of nontoxic and unstructured αSN oligomers from both monomer αSN [16] and amyloid fibrils [22]
When monomeric αSN is incubated with EGCG at low stoichiometry ([EGCG]:[αSN] = 8.7), no change in the relative NMR signal intensities of αSN is observed over 10 h, indicating that all added αSN is present in solution
Summary
Determination of the stoichiometry of EGCG binding to αSN monomer by conventional titration is complicated by the fact that αSN oligomerizes in a time-dependent manner when EGCG is present [8, 16]. Separate samples of αSN monomer were incubated with different amounts of EGCG, making sure to have identical incubation time (10 min) before recording 1D 1H-NMR spectra. Changes in the NMR spectra of both EGCG and αSN are expected upon interaction (for EGCG NMR assignments, see Fig. S1). These changes should manifest themselves as line broadening or chemical shift perturbation, with the exact outcome depending on binding kinetics [30]. The region (2.5–0.75 ppm) shows signals from aliphatic side chains (mostly methyl groups) of αSN (EGCG does not show any resonances here, see Fig. S1) and is used to gauge the fate of the protein in solution. Using 10-min incubation, all protein signals fully disappeared when the [EGCG]:[αSN] ratio was 60:1
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