Decreased Vacuolar Ca 2+ Storage and Disrupted Vesicle Trafficking Underlie Alpha-Synuclein-Induced Ca 2+ Dysregulation in S. cerevisiae

The yeast is a powerful model to study the molecular mechanisms underlying α-synuclein (α-syn) cytotoxicity. This is due to the high degree of conservation of cellular processes with higher eukaryotes and the fact that yeast does not endogenously express α-synuclein. In this work, we focused specifi...

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Bibliographic Details
Published in:Frontiers in genetics 2020, Vol.11, p.266
Main Authors: Callewaert, Geert, D'hooge, Petra, Ma, Tien-Yang, Del Vecchio, Mara, Van Eyck, Vincent, Franssens, Vanessa, Winderickx, Joris
Format: Article
Language:English
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Summary:The yeast is a powerful model to study the molecular mechanisms underlying α-synuclein (α-syn) cytotoxicity. This is due to the high degree of conservation of cellular processes with higher eukaryotes and the fact that yeast does not endogenously express α-synuclein. In this work, we focused specifically on the interplay between α-syn and intracellular Ca homeostasis. Using temperature-sensitive mutants and deletion strains for the vacuolar Ca transporters Pmc1 and Vcx1, together with aequorin-based Ca recordings, we show that overexpression of α-syn shifts the predominant temporal pattern of organellar Ca release from a biphasic to a quasi-monophasic response. Fragmentation and vesiculation of vacuolar membranes in α-syn expressing cells can account for the faster release of vacuolar Ca . α-Syn further significantly reduced Ca storage resulting in increased resting cytosolic Ca levels. Overexpression of the vacuolar Ca ATPase Pmc1 in wild-type cells prevented the α-syn-induced increase in resting Ca and was able to restore growth. We propose that α-syn-induced disruptions in Ca signaling might be an important step in initiating cell death.
ISSN:1664-8021
1664-8021
DOI:10.3389/fgene.2020.00266