Optical Sensing of the Spread of Alpha-Synuclein Aggregates in Models of Parkinson's Disease and Related Dementias
Purdue University, West Lafayette IN
Investigators
Abstract
The basis for the onset and progression of Parkinson's disease (PD) and related dementias remains unknown, but the formation and spread of aggregates of the protein alpha-synuclein (aSyn) between neurons has been identiï¬ed as a likely mechanism. Thus, understanding the molecular underpinnings of this prion-like spread is a key step that would set the stage for developing therapies to delay or alleviate PD-related motor dysfunction and dementia. However, to date, there has been no viable method to comprehensively investigate the under- lying phenomena of aggregation in live cells, and certainly not in vivo. The long-term goal of this research is to deï¬ne the molecular mechanisms that contribute to neurodegeneration in people with PD and related de- mentias, in order to stimulate the development of new therapies. The overall objective of this application is to establish a role for aSyn-mediated membrane permeabilization in the spread of aSyn neuropathology in PD. The central hypothesis is that aSyn oligomers derived from internalized preformed ï¬brils (PFFs) facilitate the endocytic escape of aSyn seeds by permeabilizing the endocytic membrane from within. This hypothesis will be addressed with the following speciï¬c aims: (i) Deï¬ne aSyn assembly states in different subcellular loca- tions of PFF-treated neurons; and (ii) Deï¬ne aSyn assembly states at various stages of PFF-mediated aSyn propagation in vivo. The project entails ï¬uorescence lifetime imaging microscopy (FLIM) studies with neurons, where lifetime depends on aggregation level, as well as steps to application in vivo, enabled by high-resolution three-dimensional ï¬uorescence localization with point-wise lifetime information (and hence insight into the aSyn self-assembly state) at various positions in the brain over time. Notably, ï¬uorescence quenching and hence lifetime reduction, similar to what occurs in ï¬uorescence resonance energy transfer (FRET), has been shown by the group to occur when aSyn fused to a ï¬uorescent protein (aSyn-FP) undergoes self-assembly to a beta- sheet-rich, aggregated state, with a lifetime that reduces with increasing aggregate size. This provides a means to study aSyn aggregate formation and spread using high-resolution FLIM (Aim 1). Drawing on the group's conceptualization and demonstration of a means to image ï¬uorescence parameters in vivo and through heavy scatter, and also at high resolution using computational imaging with localization, ï¬uorescence lifetime param- eters determined at a set of locations in the brain should yield aSyn aggregate and spread information (Aim 2). Upon completion of this project, live-cell studies will have allowed aSyn aggregation and spread to be character- ized, which should lead to understanding of the molecular process, and critical steps to optical sensing of aSyn aggregate spread in the whole brain of animals will have been achieved. This approach is innovative because it is focused on new technologies and research avenues related to the propagation of aSyn pathology in PD and related dementias. The research is signiï¬cant because the new knowledge from this study would set the stage for developing therapeutic strategies to interfere with the spread of aSyn aggregates in the brains of patients.
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