A pH-dependent switch promotes ß-synuclein fibril formation via glutamate residues.

α-Synuclein (αS) is the primary protein associated with Parkinson's disease, and it undergoes aggregation from its intrinsically disordered monomeric form to a cross-ß fibrillar form. The closely related homolog ß-synuclein (ßS) is essentially fibril-resistant under cytoplasmic physiological conditions. Toxic gain-of-function by ßS has been linked to dysfunction, but the aggregation behavior of ßS under altered pH is not well-understood. In this work, we compare fibril formation of αS and ßS at pH 7.3 and mildly acidic pH 5.8, and we demonstrate that pH serves as an on/off switch for ßS fibrillation. Using αS/ßS domain-swapped chimera constructs and single residue substitutions in ßS, we localized the switch to acidic residues in the N-terminal and non-amyloid component domains of ßS. Computational models of ßS fibril structures indicate that key glutamate residues (Glu-31 and Glu-61) in these domains may be sites of pH-sensitive interactions, and variants E31A and E61A show dramatically altered pH sensitivity for fibril formation supporting the importance of these charged side chains in fibril formation of ßS. Our results demonstrate that relatively small changes in pH, which occur frequently in the cytoplasm and in secretory pathways, may induce the formation of ßS fibrils and suggest a complex role for ßS in synuclein cellular homeostasis and Parkinson's disease.

A revised picture of the Cu(II)-α-synuclein complex: the role of N-terminal acetylation.

α-Synuclein (αS) is an amyloidogenic intrinsically disordered protein implicated in Parkinson's disease, for which copper-mediated pathways of neurodegeneration have been suggested. We have employed nuclear magnetic resonance, circular dichroism, electrospray ionization mass spectrometry, and thioflavin T fluorescence to characterize interactions of Cu(2+) with the physiological acetylated form (Ac-αS). Significantly, N-terminal acetylation abolishes Cu(2+) binding at the high-affinity M1-D2 site present in the nonacetylated protein and maintains Cu(2+) interactions around H50/D121. Fibrillation enhancement observed at an equimolar Cu(2+) stoichiometry with the nonacetylated model does not occur with Ac-αS. These findings open new avenues of investigation into Cu(2+)-mediated neurodegenerative pathology suggested in vivo.

Exploring the accessible conformations of N-terminal acetylated α-synuclein.

Alpha synuclein (αsyn) fibrils are found in the Lewy Bodies of patients with Parkinson's disease (PD). The aggregation of the αsyn monomer to soluble oligomers and insoluble fibril aggregates is believed to be one of the causes of PD. Recently, the view of the native state of αsyn as a monomeric ensemble was challenged by a report suggesting that αsyn exists in its native state as a helical tetramer. This review reports on our current understanding of αsyn within the context of these recent developments and describes the work performed by a number of groups to address the monomer/tetramer debate. A number of in depth studies have subsequently shown that both non-acetylated and acetylated αsyn purified under mild conditions are primarily monomer. A description of the accessible states of acetylated αsyn monomer and the ability of αsyn to self-associate is explored.

Mechanistic insight into the relationship between N-terminal acetylation of α-synuclein and fibril formation rates by NMR and fluorescence.

Aggregation of α-synuclein (αSyn), the primary protein component in Lewy body inclusions of patients with Parkinson's disease, arises when the normally soluble intrinsically disordered protein converts to amyloid fibrils. In this work, we provide a mechanistic view of the role of N-terminal acetylation on fibrillation by first establishing a quantitative relationship between monomer secondary structural propensity and fibril assembly kinetics, and secondly by demonstrating in the N-terminal acetylated form of the early onset A53T mutation, that N-terminal transient helices formed and/or inhibited by N-terminal acetylation modulate the fibril assembly rates. Using NMR chemical shifts and fluorescence experiments, we report that secondary structural propensity in residues 5-8, 14-31, and 50-57 are highly correlated to fibril growth rate. A four-way comparison of secondary structure propensity and fibril growth rates of N-terminally acetylated A53T and WT αSyn with non-acetylated A53T and WT αSyn present novel mechanistic insight into the role of N-terminal acetylation in amyloid fibril formation. We show that N-terminal acetylation inhibits the formation of the "fibrillation promoting" transient helix at residues 14-31 resulting from the A53T mutation in the non-acetylated variant and supports the formation of the "fibrillation inhibiting" transient helix in residues 1-12 thereby resulting in slower fibrillation rates relative to the previously studied non-acetylated A53T variant. Our results highlight the critical interplay of the region-specific transient secondary structure of the N-terminal region with fibrillation, and the inhibitory role of the N-terminal acetyl group in fibril formation.

N-terminal acetylation of α-synuclein induces increased transient helical propensity and decreased aggregation rates in the intrinsically disordered monomer.

The conformational properties of soluble α-synuclein, the primary protein found in patients with Parkinson's disease, are thought to play a key role in the structural transition to amyloid fibrils. In this work, we report that recombinant 100% N-terminal acetylated α-synuclein purified under mild physiological conditions presents as a primarily monomeric protein, and that the N-terminal acetyl group affects the transient secondary structure and fibril assembly rates of the protein. Residue-specific NMR chemical shift analysis indicates substantial increase in transient helical propensity in the first 9 N-terminal residues, as well as smaller long-range changes in residues 28-31, 43-46, and 50-66: regions in which the three familial mutations currently known to be causative of early onset disease are found. In addition, we show that the N-terminal acetylated protein forms fibrils that are morphologically similar to those formed from nonacetylated α-synuclein, but that their growth rates are slower. Our results highlight that N-terminal acetylation does not form significant numbers of dimers, tetramers, or higher molecular weight species, but does alter the conformational distributions of monomeric α-synuclein species in regions known to be important in metal binding, in association with membranes, and in regions known to affect fibril formation rates.