Structural Basis of Amyloid Oligomer Toxicity and Inhibition by Small Molecules and Molecular Chaperones

Abstract

Protein misfolding and the accumulation of insoluble aggregates is a hallmark of several neurodegenerative disorders, including Alzheimer’s (AD) and Parkinson’s disease (PD). In AD and PD patients, extracellular protein deposits consisting of amyloid beta (Aβ) and intraneuronal inclusions composed of alpha synuclein (αS) are observed, respectively. Notably, the spatiotemporal patterning of soluble protein oligomers of αS and Aβ closely follow disease progression, giving support to an emerging role of soluble oligomers in PD and AD pathogenesis. However, the structural features underlying the toxicity of Aβ and αS oligomers remain elusive. This doctoral dissertation aims at elucidating the structural determinants of oligomer toxicity by focusing on the development and application of multidisciplinary approaches based primarily on solution NMR in combination with electron microscopy, multi-angle light scattering, fluorescence microscopy, wide-angle x-ray diffraction and cellular biophysics. Using this interdisciplinary approach, in chapters 2 and 3, we identify at atomic resolution the key structural elements that facilitate the colocalization, interaction and subsequent insertion of soluble Aβ oligomers into membranes, which ultimately result in the loss of membrane integrity. Notably, we show that small molecules, such as green tea catechins, remodel these structural features and effectively perturb the interactions with membranes. In chapter 4, we extend these analyses to αS and identify how the chaperone, Human Serum Albumin (HSA), remodels toxic αS oligomers into non-toxic species and breaks the catalytic cycle that generates new toxic oligomers. Lastly, in chapter 5, we describe a novel solution NMR approach to map at atomic resolution the sites of early self-association, with minimal bias from monomer dynamics, an effect that frequently dominates residue-dependent variations in solution NMR measurements. Overall, given that Aβ and αS are archetypical amyloidogenic proteins, we anticipate that the structure – toxicity relationships established herein, and the related experimental approaches may be transferrable to other amyloidogenic systems.