Abstract
The aggregation of α-synuclein (α-syn) into amyloid fibrils is associated with neurodegenerative diseases, collectively referred to as the α-synucleinopathies. In vivo, molecular chaperones, such as the small heat-shock proteins (sHsps), normally act to prevent protein aggregation; however, it remains to be determined how aggregation-prone α-syn evades sHsp chaperone action leading to its disease-associated deposition. This work examines the molecular mechanism by which two canonical sHsps, αB-crystallin (αB-c) and Hsp27, interact with aggregation-prone α-syn to prevent its aggregation in vitro. Both sHsps are very effective inhibitors of α-syn aggregation, but no stable complex between the sHsps and α-syn was detected, indicating that the sHsps inhibit α-syn aggregation via transient interactions. Moreover, the ability of these sHsps to prevent α-syn aggregation was dependent on the kinetics of aggregation; the faster the rate of aggregation (shorter the lag phase), the less effective the sHsps were at inhibiting fibril formation of α-syn. Thus, these findings indicate that the rate at which α-syn aggregates in cells may be a significant factor in how it evades sHsp chaperone action in the α-synucleinopathies.
Highlights
␣-Synuclein (␣-syn)5 is a protein primarily found in neuronal tissue, where it is predominantly localized to presynaptic terminals [1]
The small heat-shock proteins (sHsps) play a critical role in maintaining cellular proteostasis by preventing protein aggregation associated with disease
We confirm that the sHsps ␣B-c and Hsp27 are potent inhibitors of ␣-syn fibril formation in vitro [37, 54, 55]
Summary
␣-Synuclein (␣-syn) is a protein primarily found in neuronal tissue, where it is predominantly localized to presynaptic terminals [1]. The definitive function of ␣-syn is yet to be established, it has been implicated in modulating synaptic activity through membrane processes, including membrane biogenesis, vesicular trafficking, and neurotransmitter release [2, 3] It has traditionally been considered an intrinsically disordered protein [4, 5], there have been recent studies indicating that it may form an ␣-helical tetramer in vivo [6, 7]. The larger oligomers are regarded as reservoirs of these chaperone-active dissociated forms Based on this model, the rate of subunit exchange governs the speed of production of chaperone-active species capable of interacting with aggregation-prone states of target proteins. We show that these chaperones prevent ␣-syn aggregation through transient interactions and that the chaperone efficacy of these sHsps in preventing ␣-syn fibril formation is highly dependent upon the rate at which ␣-syn aggregates
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