The aggregation of ␣-synuclein (AS) is characteristic of Parkinson's disease and other neurodegenerative synucleinopathies. We demonstrate here that Cu(II) ions are effective in accelerating AS aggregation at physiologically relevant concentrations without altering the resultant fibrillar structures. By using numerous spectroscopic techniques (absorption, CD, EPR, and NMR), we have located the primary binding for Cu(II) to a specific site in the N terminus, involving His-50 as the anchoring residue and other nitrogen͞oxygen donor atoms in a square planar or distorted tetragonal geometry. The carboxylate-rich C terminus, originally thought to drive copper binding, is able to coordinate a second Cu(II) equivalent, albeit with a 300-fold reduced affinity. The NMR analysis of AS-Cu ( amyloid ͉ fibrillation ͉ metallobiology T he protein ␣-synuclein (AS) is the main component of neuronal and glial cytoplasmic inclusions, pathologically described as Lewy bodies, that constitute the hallmark lesions of a group of neurodegenerative diseases collectively referred to as synucleinopathies (1, 2). The identification of point mutations and locus triplication in the AS gene as sole causes of familial inherited Parkinson's disease (PD) (3, 4) has stimulated research on the mechanism of AS neurotoxicity.AS comprises 140 amino acids distributed in three different regions: (i) the amphipathic N terminus (residues 1-60); (ii) the highly hydrophobic self-aggregating sequence known as NAC (non-A component, residues 61-95), which is presumed to initiate fibrillation (5); and (iii) the acidic C-terminal region (residues 96-140). In its native monomeric state, AS adopts an ensemble of conformations with no significant secondary structure (6, 7), although long-range interactions have been shown to stabilize an aggregation-autoinhibited global protein architecture (8, 9). The protein undergoes dramatic conformational transitions from its natively unstructured state to an ␣-helical conformation upon interaction with lipid membranes (10, 11) or to the characteristic crossed -conformation in highly organized amyloid-like fibrils under conditions that trigger aggregation (12, 13). Whereas the mechanism for the ␣-helical transition is well understood, the detailed mechanism of amyloid formation remains to be elucidated.The kinetics of fibrillation of AS are consistent with a nucleation-dependent mechanism (14), being modulated by factors and effectors of different types. Among them, low pH and high temperature (15-17), organic solvents (18), heparin (19), polyamines (14,20), and metal cations (21-23) accelerate AS aggregation. Not only do metal cations exert a physiological influence on protein structure, but transition metals have been also frequently recognized as risk factors in neurodegenerative disorders (24, 25). Brain lesions associated with Alzheimer's disease (AD) are rich in Fe(III), Zn(II), and Cu(II) (26). Recent biophysical and structural studies of the amyloid precursor protein and the amyloid- peptide (A) have provided stron...
