α-Synuclein interacts with the switch region of Rab8a in a Ser129 phosphorylation-dependent manner.

Alpha-synuclein (αS) misfolding is associated with Parkinson's disease (PD) but little is known about the mechanisms underlying αS toxicity. Increasing evidence suggests that defects in membrane transport play an important role in neuronal dysfunction. Here we demonstrate that the GTPase Rab8a interacts with αS in rodent brain. NMR spectroscopy reveals that the C-terminus of αS binds to the functionally important switch region as well as the C-terminal tail of Rab8a. In line with a direct Rab8a/αS interaction, Rab8a enhanced αS aggregation and reduced αS-induced cellular toxicity. In addition, Rab8 - the Drosophila ortholog of Rab8a - ameliorated αS-oligomer specific locomotor impairment and neuron loss in fruit flies. In support of the pathogenic relevance of the αS-Rab8a interaction, phosphorylation of αS at S129 enhanced binding to Rab8a, increased formation of insoluble αS aggregates and reduced cellular toxicity. Our study provides novel mechanistic insights into the interplay of the GTPase Rab8a and αS cytotoxicity, and underscores the therapeutic potential of targeting this interaction.

Structural comparison of mouse and human α-synuclein amyloid fibrils by solid-state NMR.

Fibrillar α-synuclein (AS) is the major component of Lewy bodies, the pathological hallmark of Parkinson's disease. Mouse AS (mAS) aggregates much faster than human AS (hAS), although mAS differs from hAS at only seven positions in its primary sequence. Currently, little is known about the site-specific structural differences between mAS and hAS fibrils. Here, we applied state-of-the-art solid-state nuclear magnetic resonance (ssNMR) methods to structurally characterize mAS fibrils. The assignment strategy employed a set of high-resolution 2D and 3D ssNMR spectra recorded on uniformly [(13)C, (15)N], [1-(13)C]glucose, and [2-(13)C]glucose labeled mAS fibrils. An almost complete resonance assignment (96% of backbone amide (15)N and 93% of all (13)C nuclei) was obtained for residues from Gly41 to Val95, which form the core of mAS fibrils. Six ß-strands were identified to be within the fibril core of mAS based on a secondary chemical shift and NHHC analysis. Intermolecular (13)C:(15)N labeled restraints obtained from mixed 1:1 (13)C/(15)N-labeled mAS fibrils reveal a parallel, in-register supramolecular ß-sheet arrangement. The results were compared in detail to recent structural studies on hAS fibrils and indicate the presence of a structurally conserved motif comprising residues Glu61-Lys80.

Structures behind the amyloid aggregation of α-synuclein: an NMR based approach.

The misfolding of proteins into a toxic conformation is proposed to be at the molecular foundation of a number of neurodegenerative disorders including Alzheimer's and Parkinson's diseases. Evidence that α-synuclein amyloidogenesis plays a causative role in the development of Parkinson's disease is furnished by a variety of genetic, neuropathological and biochemical studies. There is a major interest in understanding the structural and toxicity features of the various species populated along the aggregation pathway of this protein. The development of multidimensional nuclear magnetic resonance (NMR) spectroscopy in liquid and solid state over the last decade has significantly increased the scope of molecules that are amenable for structural studies. The aim of this review is to provide a picture of how NMR tools were used in concert to decipher the structural and dynamic properties of the intrinsically disordered protein α-synuclein in its native, oligomeric, fibril and membrane-bound states. Understanding the structural and molecular basis behind the aggregation pathway of α-synuclein is key to advance in the design of a therapeutic strategy.

Structural and mechanistic basis behind the inhibitory interaction of PcTS on alpha-synuclein amyloid fibril formation.

The identification of aggregation inhibitors and the investigation of their mechanism of action are fundamental in the quest to mitigate the pathological consequences of amyloid formation. Here, characterization of the structural and mechanistic basis for the antiamyloidogenic effect of phthalocyanine tetrasulfonate (PcTS) on alpha-synuclein (AS) allowed us to demonstrate that specific aromatic interactions are central for ligand-mediated inhibition of amyloid formation. We provide evidence indicating that the mechanism behind the antiamyloidogenic effect of PcTS is correlated with the trapping of prefibrillar AS species during the early stages of the assembly process. By using NMR spectroscopy, we have located the primary binding region for PcTS to a specific site in the N terminus of AS, involving the amino acid Tyr-39 as the anchoring residue. Moreover, the residue-specific structural characterization of the AS-PcTS complex provided the basis for the rational design of nonamyloidogenic species of AS, highlighting the role of aromatic interactions in driving AS amyloid assembly. A comparative analysis with other proteins involved in neurodegenerative disorders reveals that aromatic recognition interfaces might constitute a key structural element to target their aggregation pathways. These findings emphasize the use of aggregation inhibitors as molecular probes to assess structural and toxic mechanisms related to amyloid formation and the potential of small molecules as therapeutics for amyloid-related pathologies.